Objective lens element and optical head device including the same

ABSTRACT

An objective lens element having improved diffraction efficiency at at least one of used wavelengths is provided. The objective lens element includes one surface including: a first region including an optical axis; and a second region surrounding the first region. A periodic first diffraction structure is formed on the first region, and a periodic second diffraction structure different from the first diffraction structure is formed on the second region. The objective lens element satisfies the following conditions. 
       | A 1− B 1|&lt;| A 2− B 2|  (1)
 
       | B 1|≧| B 2|  (2)
 
     Here,
         A1 and B1 are diffraction orders at the first region to converge light of a first wavelength and light of a second wavelength on a recording surface, respectively, and   A2 and B2 are diffraction orders at the second region to converge the light of the first wavelength and the light of the second wavelength on a recording surface, respectively.

CROSS REFERENCE TO RELATED APPLICATION

The disclosure of Japanese Patent Application Nos. 2011-029371, filed on Feb. 15, 2011, and 2012-29063, filed on Feb. 14, 2012, is incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an objective lens element used for performing at least one of recording, reproducing, and erasing of information on an optical information medium such as an optical disc, and an optical head device including the objective lens element.

2. Description of the Background Art

In recent years, research and development has been actively carried out concerning high-density optical discs that have an increased recording density and thus have an increased storage capacity. A standard of such a high-density optical disc is Blu-Ray (R) Disc (hereinafter, referred to as “BD”) in which the image side numerical aperture (NA) of an objective lens element is set to about 0.85 and the thickness of a protective base plate formed on an information recording surface of an optical disc is set to about 0.1 mm.

In addition to the above BD standard, a standard (so-called DVD standard) in which a red laser beam with a wavelength of about 680 nm is used and the thickness of a protective base plate formed on an information recording surface of an optical disc is set to about 0.6 mm, and a standard (so-called CD standard) in which an infrared laser beam with a wavelength of about 780 nm is used and the thickness of a protective base plate is set to about 1.2 mm, have also been used. Various objective lens elements that are compatible with at least two of these three standards have been developed.

For example, an objective lens element that is compatible with two types of information storage media, BD and DVD, and an objective lens element that is compatible with three types of information storage media, BD, DVD, and CD, are known (for the latter, for example, see Japanese Laid-Open Patent Publication No. 2010-170694).

In the objective lens element that is compatible with two types of information storage media, BD and DVD, a first surface is divided into two regions which are concentric about a symmetry axis (optical axis), a compatible region which performs aberration compensation for two types of wavelengths for BD and DVD is formed in the region close to the optical axis, and an outer region optimized for BD is formed outside the compatible region. The compatible region has a diffraction structure and achieves spherical aberration compensation for two types of formats of BD and DVD by using a difference in diffraction angle caused by a difference in wavelength. It should be noted that the first surface refers to a surface located closer to a light source, among two optically functional surfaces of the objective lens element. In other words, the first surface is an incident surface of the objective lens element. In addition, a surface opposed to the first surface is referred to as a second surface. In other words, the second surface is an exit surface of the objective lens element.

In the objective lens element that is compatible with three types of information storage media, BD, DVD, and CD, a first surface is divided into three regions which are concentric about the optical axis, a compatible region which performs aberration compensation for three types of wavelengths for BD, DVD, and CD is formed in the region closest to the optical axis, another compatible region which performs aberration compensation for two types of wavelengths for BD and DVD is formed outside the compatible region, and an outer region optimized for BD is formed outside the other compatible region. The compatible region has a diffraction structure and achieves spherical aberration compensation for three types of formats of BD, DVD, and CD by using a difference in diffraction angle caused by a difference in wavelength.

However, when the objective lens element having the above configuration is used, it is necessary to increase the diffraction power of the compatible region in order to ensure a sufficient working distance (in particular, when DVD or CD is used) while aberration compensation is performed for a plurality of formats.

When the diffraction power is increased, the interval of the periodic diffraction structure in the compatible region narrows as distance from the optical axis of the objective lens element increases.

When the interval of the diffraction structure narrows, the diffraction efficiency decreases. As a result, an amount of light passing through the compatible region decreases. Thus, in the conventional objective lens element, performance sufficient to perform recording, reproducing, and erasing of information on an optical information medium such as an optical disc is not obtained.

Further, the interval of the diffraction structure narrows as distance from the optical axis increases. When the interval of the diffraction shape narrows, an amount of light at a peripheral portion of the compatible region greatly decreases. When DVD or CD is used, it is necessary to form a predetermined convergence spot only with light passing through the compatible region. Thus, when an amount of light which determines a numerical aperture for DVD or CD decreases, the numerical aperture effectively decreases. As a result, reproducing/recording performance deteriorates, since a convergence spot on the optical disc effectively enlarges.

SUMMARY OF THE INVENTION

Therefore, the present invention provides an objective lens element having improved diffraction efficiency at least one of a plurality of used wavelengths.

The present invention is directed to an objective lens element capable of converging each of fight of a first wavelength and light of a second wavelength longer than the first wavelength, on an information recording surface of an optical disc. The objective lens element includes one surface including: a first region including an optical axis; and a second region surrounding the first region. Aperiodic first diffraction structure is formed on the first region. A periodic second diffraction structure that is different from the first diffraction structure is formed on the second region. The objective lens element satisfies the following condition formulas.

|A1−B1|<|A2−B2|  (1)

|B1|≧|B2|  (2)

Here

A1 is a diffraction order at the first region to converge the light of the first wavelength on the information recording surface,

B1 is a diffraction order at the first region to converge the light of the second wavelength on the information recording surface,

A2 is a diffraction order at the second region to converge the light of the first wavelength on the information recording surface, and

B2 is a diffraction order at the second region to converge the light of the second wavelength on the information recording surface.

Further, the present invention is directed to an objective lens element capable of converging each of light of a first wavelength, light of a second wavelength longer than the first wavelength, and light of a third wavelength longer than the second wavelength, on an information recording surface of an optical disc. The objective lens element satisfies the following conditions.

L1<0  (3)

L2>0  (4)

Here

L1 is the distance from an incident surface of the objective lens element to an object point of a light source of the second wavelength, and

L2 is the distance from the incident surface of the objective lens element to an object point of a light source of the third wavelength.

According to the present invention, diffraction efficiency improves at at least one of a plurality of used wavelengths.

These and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic configuration diagram of an optical head device including an objective lens element according to a first embodiment;

FIG. 2 is a schematic cross-sectional view of the objective lens element according to the first embodiment;

FIG. 3 is a partially enlarged view showing a diffraction shape of the objective lens element according to the first embodiment;

FIG. 4 is a schematic configuration diagram of an optical head device including an objective lens element according to a second embodiment;

FIG. 5 is a schematic cross-sectional view of the objective lens element according to the second embodiment;

FIG. 6 is a partially enlarged view showing a diffraction shape of the objective lens element according to the second embodiment;

FIG. 7A is an optical path diagram of an objective lens element according to a third embodiment (when DVD is used);

FIG. 7B is an optical path diagram of the objective lens element according to the third embodiment (when CD is used);

FIG. 8 is a partially enlarged view showing a diffraction shape of an objective lens element according to Example 1;

FIG. 9 is a partially enlarged view showing a diffraction shape of an objective lens element according to Example 2;

FIG. 10 is a partially enlarged view showing a diffraction shape of an objective lens element according to Example 3;

FIG. 11 is a partially enlarged view showing a diffraction shape of an objective lens element according to Example 4;

FIG. 12 is a partially enlarged view showing a diffraction shape of an objective lens element according to Example 5;

FIG. 13 is a partially enlarged view showing a diffraction shape of an objective lens element according to Example 6; and

FIG. 14 is a partially enlarged view showing a diffraction shape of an objective lens element according to Example 7.

DESCRIPTION OF THE PREFERRED EMBODIMENTS First Embodiment 1. Configuration of Optical Head Device

FIG. 1 is a schematic configuration diagram of an optical head device including an objective lens element according to a first embodiment. A blue light beam 61 described below corresponds to a light of the wavelength λ1. The wavelength λ1 is an example of first wavelength. Further, a red light beam described below corresponds to a light of the wavelength λ2. The wavelength λ2 is an example of second wavelength.

The optical head device according to the first embodiment is configured to be compatible with the BD standard and the DVD standard.

A blue light beam 61 emitted from a laser beam source 1 passes through a relay lens 2 and a three-beam grating 3, is reflected by a beam splitter 4, and then is converted into a substantially parallel light beam by a collimating lens 8. The collimating lens 8 is movable in an optical axis direction. By moving in the optical axis direction, the collimating lens 8 compensates for a spherical aberration caused by an error of a base material thickness of an optical disc and a spherical aberration caused by a difference in base material thickness between information recording surfaces in a medium having multiple information recording surfaces. The blue light beam 61 having passed through the collimating lens 8 passes through a quarter wavelength plate 5, is reflected by an upward reflection mirror 12, is incident on the objective lens element 143, and is converged on an information recording surface of an optical disc 9 to form a desired spot thereon. The blue light beam 61 reflected by an information recording surface of an optical disc 9 passes through the objective lens element 143 again, is reflected by the upward reflection mirror 12, and passes through the quarter wavelength plate 5, the collimating lens 8, and the beam splitter 4 in order. The blue light beam 61 outputted from the beam splitter 4 is reflected by a beam splitter 16, is converged on a photodetector 33 by a detection lens 32, and is detected as an optical signal by the photodetector 33.

A red light beam 62 emitted from a laser beam source 20 passes through a three-beam grating 22, the beam splitter 16 and the beam splitter 4, is incident on the collimating lens 8, and is converted into diverging light. The collimating lens 8 can adjust the parallelism of the red light beam 62 by moving in the optical axis direction. In addition, similarly to the case where the optical disc 9 is used, by moving in the optical axis direction, the collimating lens 8 compensates for a spherical aberration caused by a difference in base material thickness of an optical disc, a temperature change, a wavelength change, and the like. The red light beam 62 having passed through the collimating lens 8 passes through the quarter wavelength plate 5, is reflected as diverging light by the upward reflection mirror 12, is incident on the objective lens element 143, and is converged on an information recording surface of an optical disc 10 to form a desired spot thereon. The red light beam 62 reflected by the information recording surface of the optical disc 10 passes through the objective lens element 143 again, is reflected by the upward reflection mirror 12, and passes through the quarter wavelength plate 5, the collimating lens 8, and the beam splitter 4 in order. The red light beam 62 outputted from the beam splitter 4 is reflected by the beam splitter 16, is converged on the photodetector 33 by the detection lens 32, and is detected as an optical signal by the photodetector 33.

2. Description of Objective Lens Element

Next, the objective lens element 143 according to the present embodiment will be described. FIG. 2 is a schematic cross-sectional view of the objective lens element 143 according to the first embodiment.

The objective lens element 143 according to the first embodiment is compatible with the BD standard and the DVD standard, converges blue light of a wavelength λ1 (about 400 nm) on an information recording surface through a base plate having a thickness of 0.1 mm to form a spot thereon, and converges red light of a wavelength λ2 (about 680 nm) on an information recording surface through a base plate having a thickness of 0.6 mm to form a spot thereon.

An incident side optically functional surface of the objective lens element 143 is divided into three regions each having a center on the optical axis, namely, a first region 131A including the optical axis, a ring-shaped second region 131B surrounding the first region 131A, and a ring-shaped outer region 131F surrounding the second region 131B. A stair-like diffraction structure is provided on the first region 131A. A stair-like diffraction structure that is different from that provided on the first region 131A is provided on the second region 131B. A sawtooth-like diffraction structure is provided on the outer region 131F.

Each of the first region 131A and the second region 131B is a region which contributes to formation of spots of light with two wavelengths for BD and DVD. Meanwhile, the outer region 131F is a region dedicated for BD, which contributes to formation of a spot of only light for BD.

3. Description of Diffraction Structure

Next, the diffraction structure of the objective lens element 143 according to the present embodiment will be described. FIG. 3 is a partially enlarged view for illustrating the diffraction structure of the objective lens element 143. In FIG. 3, a broken line represents the surface shape of the diffraction structure, a portion below the broken line is a lens material such as glass, and a portion above the broken line is air. It should be noted that in later-described partially enlarged views of diffraction structures, similarly, a portion below a broken line is a lens material, and a portion above a broken line is air.

The objective lens element 143 according to the present embodiment mainly includes the first region 131A, the second region 131B, and the outer region 131F.

In the objective lens element 143 according to the present embodiment, the diffraction structure formed on the first region 131A, the diffraction structure formed on the second region 131B, and the diffraction structure formed on the outer region 131F have different shapes, respectively. The diffraction structure shown in FIG. 3 is an example and may be a diffraction structure of another shape. In addition, the shapes of connection portions between the diffraction structures which are shown in FIG. 3 are examples, and the shapes of the connection portions between the diffraction structures can be set as appropriate.

Hereinafter, each region will be described.

The stair-like diffraction structure provided on the first region 131A is a periodic structure in which one cycle is composed of 4-level steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases. Here, the level number indicates the number of portions substantially parallel to the base surface of the objective lens element, in one cycle of the periodic structure.

The step height of the stair-like diffraction structure of the first region 131A is set such that the diffraction efficiency of +1st order diffracted light is at its maximum when the blue light of the wavelength λ1 is used and the diffraction efficiency of −1st order diffracted light is at its maximum when the red light of the wavelength λ2 is used. Here, positive and negative of diffraction order will be described. First, a direction in which light incident on the first surface is refracted is set as a reference direction. When light incident on the first surface travels in a direction in which the light is converged toward the inner side of the reference direction (the optical axis side) by diffraction at the second surface, the diffraction order is positive. In addition, when light incident on the first surface travels in a direction in which the light is converged toward the outer side of the reference direction (the outer periphery side) by diffraction, the diffraction order is negative.

One cycle of the stair-like diffraction structure provided on the first region 131A does not necessarily have to be composed of 4-level steps and may be composed of steps other than 4-level steps.

The stair-like diffraction structure provided on the second region 131B is a periodic structure in which one cycle is composed of 4-level steps whose height monotonically increases step by step as distance from the optical axis of the objective lens element increases.

The step height of the stair-like diffraction structure of the second region 131B is set such that the diffraction efficiency of +2nd order diffracted light is at its maximum when the blue light of the wavelength λ1 is used and the diffraction efficiency of −1st order diffracted light is at its maximum when the red light of the wavelength λ2 is used. One cycle of the stair-like diffraction structure provided on the second region 131B does not necessarily have to be composed of 4-level steps and may be composed of steps other than 4-level steps. In addition, in the present embodiment, a value with which the diffraction efficiency at each wavelength is at its maximum is selected as the diffraction order, but a value with which the diffraction efficiency is not at its maximum may be used as the diffraction order.

The height of the sawtooth-like diffraction structure provided on the outer region 131F is set such that the diffraction efficiency of +3rd order diffracted light is at its maximum when the light of the wavelength λ1 for BD is used. The diffraction order having the maximum diffraction efficiency may be a diffraction order other than +3rd order. However, the outer region 131F is a region dedicated for BD, and thus preferably has an aperture limiting function for adjusting an effective NA, with respect to light of a wavelength other than light for BD. In other words, it is desired that light of a wavelength other than the wavelength which is incident on the outer region 131F, does not contribute to a spot and does not return as stray light onto the photodetector 33. The stray light refers to light which is reflected by a surface of an optical disc, a recording surface of the optical disc, an optical component on an optical path, a lens surface, or the like and which influences the intensity of signal light on the photodetector.

4. Regarding Characteristic Portions

The objective lens element 143 according to the present embodiment satisfies the following condition formulas (1) and (2).

|A1−B1|<|A2−B2|  (1)

|B1|≧|B2|  (2)

Here,

A1 is the diffraction order at the first region to converge the light of the wavelength λ1 on the information recording surface,

B1 is the diffraction order at the first region to converge to the light of the wavelength λ2 on the information recording surface,

A2 is the diffraction order at the second region to converge the light of the wavelength λ1 on the information recording surface, and

B2 is the diffraction order at the second region to converge the light of the wavelength λ2 on the information recording surface.

By selecting the diffraction order at the first region 131A and the diffraction order at the second region 131B such that the condition formulas (1) and (2) are satisfied, the width of each ring zone constituting the periodic structure of the second region 131B can be made larger than the width of each ring zone constituting the periodic structure of the first region 131A. As a result, the diffraction efficiency improves. The reason why the diffraction efficiency improves will be described below.

First, the working distances for BD and DVD will be described. The working distance is the distance between the objective lens element 143 and a surface of an information storage medium.

When the working distance is shortened, there is the possibility that the objective lens element 143 and the information storage medium will be brought into contact with each other. However, in the case of BD, when the working distance is lengthened, the focal distance increases, and thus the diameter of the objective lens element has to be increased in order to obtain a desired numerical aperture. In addition, when the working distance is long, deterioration of performance caused by a manufacturing error is great. Thus, it is difficult to lengthen the working distance when BD is used.

Meanwhile, regarding DVD, sufficient performance can be ensured even when the working distance is lengthened to some extent as compared to BD. Thus, the working distance when DVD is used can be set so as to be long to some extent, in order to prevent the objective lens element 143 and the information storage medium (here, DVD) from being brought into contact with each other.

In order to lengthen the working distance for DVD, it is necessary to increase diffraction power.

In order to increase the diffraction power, it is necessary to shorten the cycle of the diffraction structure. However, when the cycle of the diffraction structure is shortened, the diffraction efficiency decreases. In particular, the diffraction efficiency of light for DVD decreases. As a result, performance required for DVD cannot be realized.

Thus, in the present embodiment, in order to prevent the diffraction efficiency of light of at least one wavelength (here, the diffraction efficiency of light for DVD) from decreasing, the diffraction order for BD at the first region 131A is set to +1st order, the diffraction order for DVD at the first region 131A is set to −1st order, the diffraction order for BD at the second region 131B is set to +2nd order, and the diffraction order for DVD at the second region 131B is set to −1st order.

As described above, in the present embodiment, the diffraction order for the light for BD at the second region 131B is made higher than the diffraction order for the light for BD at the first region 131A, and the diffraction order for the light for DVD at the second region 131B is made the same as the diffraction order for the light for DVD at the first region 131A. In other words, the difference between the diffraction order for BD and the diffraction order for DVD at the second region 131B is made greater than the difference between the diffraction order for BD and the diffraction order for DVD at the first region 131A.

When a difference in diffraction order is great, the angular difference between diffracted light for BD and diffracted light for DVD also increases. In order to converge diffracted light for BD or diffracted light for DVD, which has passed through the first region 131A and the second region 131B, to form a desired spot in a state where a difference in diffraction order is great, it is necessary to decrease the angular difference between the diffracted light for BD and the diffracted light for DVD in the second region 131B. Thus, in order to decrease the angular difference between the diffracted light for BD and the diffracted light for DVD, the diffraction power of the second region 131B is decreased.

Since the diffraction power is decreased, the cycle of the diffraction structure can be widened. By widening the cycle of the diffraction structure, decrease of the diffraction efficiency can be prevented. In the case of the present embodiment, the diffraction efficiency of the light for DVD greatly improves.

Second Embodiment 1. Description of Optical Head Device

FIG. 4 is a schematic configuration diagram of an optical head device including an objective lens element according to a second embodiment.

The optical head device according to the second embodiment is configured to be compatible with the BD standard, the DVD standard, and the CD standard. A blue light beam 61 described below corresponds to a light of the wavelength λ1. The wavelength λ1 is an example of first wavelength. Further, a red light beam described below corresponds to a light of the wavelength λ2. The wavelength λ2 is an example of second wavelength. Further, an infrared light beam 63 corresponds to the wavelength λ3. The wavelength λ3 is an example of third wavelength.

A blue light beam 61 emitted from a laser beam source 1 passes through a relay lens 2 and a three-beam grating 3, is reflected by a beam splitter 4, and then is converted into a substantially parallel light beam by a collimating lens 8. The collimating lens 8 is movable in an optical axis direction. By moving in the optical axis direction, the collimating lens 8 compensates for a spherical aberration caused by an error of a base material thickness of an optical disc and a spherical aberration caused by a difference in base material thickness between information recording surfaces in a medium having multiple information recording surfaces. The blue light beam 61 having passed through the collimating lens 8 passes through a quarter wavelength plate 5, is reflected by an upward reflection mirror 12, is incident on the objective lens element 163, and is converged on an information recording surface of an optical disc 9 to form a desired spot thereon. The blue light beam 61 reflected by the information recording surface of the optical disc 9 passes through the objective lens element 163 again, is reflected by the upward reflection mirror 12, and passes through the quarter wavelength plate 5, the collimating lens 8, and the beam splitter 4 in order. The blue light beam 61 outputted from the beam splitter 4 is reflected by a beam splitter 16, is converged on a photodetector 33 by a detection lens 32, and is detected as an optical signal by the photodetector 33.

A laser beam source 20 according to the present embodiment is a two-wavelength laser beam source which selectively emits red light and infrared light. A red light beam 62 emitted from a laser beam source 20 passes through a three-beam grating 22, the beam splitter 16, and the beam splitter 4, is incident on the collimating lens 8, and is converted into diverging light. The collimating lens 8 can adjust the parallelism of the red light beam 62 by moving in the optical axis direction. In addition, similarly to the case where the optical disc 9 is used, by moving in the optical axis direction, the collimating lens 8 compensates for a spherical aberration caused by a difference in base material thickness of an optical disc, a temperature change, a wavelength change, and the like. The red light beam 62 having passed through the collimating lens 8 passes through the quarter wavelength plate 5, is reflected as diverging light by the upward reflection mirror 12, is incident on the objective lens element 163, and is converged on an information recording surface of an optical disc 10 to form a desired spot thereon. The red light beam 62 reflected by the information recording surface of the optical disc 10 passes through the objective lens element 163 again, is reflected by the upward reflection mirror 12, and passes through the quarter wavelength plate 5, the collimating lens 8, and the beam splitter 4 in order. The red light beam 62 outputted from the beam splitter 4 is reflected by the beam splitter 16, is converged on the photodetector 33 by the detection lens 32, and is detected as an optical signal by the photodetector 33.

An infrared light beam 63 emitted from the laser beam source 20 passes through the three-beam grating 22, the beam splitter 16, and the beam splitter 4, is incident on the collimating lens 8, and is converted into diverging light. The infrared light beam 63 outputted from the collimating lens 8 passes through the quarter wavelength plate 5, is reflected by the upward reflection mirror 12, is incident on the objective lens element 163, and is converged on an information recording surface of an optical disc 11 to form a desired spot thereon. The infrared light beam 63 reflected by the information recording surface of the optical disc 11 passes through the objective lens element 163 again, is reflected by the upward reflection mirror 12, passes through the quarter wavelength plate 5, the collimating lens 8, and the beam splitter 4 in order, and is reflected by the beam splitter 16. Then, the infrared light beam 63 is converged by the detection lens 32 and detected as an optical signal by the photodetector 33.

2. Description of Objective Lens Element

Next, the objective lens element 163 according to the present embodiment will be described. FIG. 5 is a schematic cross-sectional view of the objective lens element 163 according to the present embodiment.

The objective lens element 163 according to the second embodiment is compatible with the BD standard, the DVD standard, and the CD standard, converges blue light of a wavelength λ1 (about 400 nm) on an information recording surface through a base plate having a thickness of 0.1 mm to form a spot thereon, converges red light of a wavelength λ2 (about 680 nm) on an information recording surface through a base plate having a thickness of 0.6 mm to form a spot thereon, and converges infrared light of a wavelength λ3 (about 780 nm) on an information recording surface through a base plate having a thickness of 1.2 mm to form a spot thereon.

An incident side optically functional surface of the objective lens element 163 is divided into four regions each having a center on the optical axis, namely, a first region 151A including the optical axis, a ring-shaped second region 151B surrounding the first region 151A, a ring-shaped third region 151C surrounding the second region 151B, and a ring-shaped outer region 151F surrounding the third region 151C. Stair-like diffraction structures that are different from each other are provided on the first region 151A, the second region 151B, and the third region 151C, respectively. A sawtooth-like diffraction structure is provided on the outer region 151F.

Each of the first region 151A and the second region 151B is a region which contributes to formation of spots of light with three wavelengths for BD, DVD, and CD. The third region 151C is a region which contributes to formation of spots of light with two wavelengths for BD and DVD. The outer region 151F is a region dedicated for BD, which contributes to formation of a spot of only light for BD.

3. Description of Diffraction Structure

Next, the diffraction structure of the objective lens element 163 according to the present embodiment will be described. FIG. 6 is a partially enlarged view for illustrating the diffraction structure of the objective lens element 163.

The objective lens element 163 according to the present embodiment mainly includes the first region 151A, the second region 151B, the third region 151C, and the outer region 151F.

In the objective lens element 163 according to the present embodiment, the diffraction structure formed on the first region 151A, the diffraction structure formed on the second region 151B, the diffraction structure formed on the third region 151C, and the diffraction structure formed on the outer region 151F have different shapes, respectively. The diffraction structure shown in FIG. 6 is an example and may be a diffraction structure of another shape. In addition, the shapes of connection portions between the diffraction structures which are shown in FIG. 6 are examples, and the shapes of the connection portions between the diffraction structures can be set as appropriate.

Hereinafter, each region will be described.

The stair-like diffraction structure provided on the first region 151A is a periodic structure in which one cycle is composed of 6-level steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element 163 increases. Here, the level number indicates the number of portions substantially parallel to the base surface of the objective lens element 163, in one cycle of the periodic structure.

The step height of the stair-like diffraction structure of the first region 151A is set such that the diffraction efficiency of +2nd order diffracted light is at its maximum when the blue light of the wavelength λ1 is used, the diffraction efficiency of −1st order diffracted light is at its maximum when the red light of the wavelength λ2 is used, and the diffraction efficiency of −2nd order diffracted light is at its maximum when the infrared light of the wavelength λ3 is used. Here, positive and negative of diffraction order will be described. First, a direction in which light incident on the first surface is refracted is set as a reference direction. When light incident on the first surface travels in a direction in which the light is converged toward the inner side of the reference direction (the optical axis side) by diffraction at the second surface, the diffraction order is positive.

One cycle of the stair-like diffraction structure provided on the first region 151A does not necessarily have to be composed of 6-level steps and may be composed of steps other than 6-level steps.

The stair-like diffraction structure provided on the second region 151B is a periodic structure in which one cycle is composed of 8-level steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element 163 increases. The step height of the stair-like diffraction structure of the second region 151B is set such that the diffraction efficiency of +2nd order diffracted light is at its maximum when the blue light of the wavelength λ1 is used, the diffraction efficiency of −2nd order diffracted light is at its maximum when the red light of the wavelength λ2 is used, and the diffraction efficiency of −3rd order diffracted light is at its maximum when the infrared light of the wavelength λ3 is used. One cycle of the stair-like diffraction structure provided on the second region 151B does not necessarily have to be composed of 8-level steps and may be composed of steps other than 8-level steps. In addition, in the present embodiment, a value with which the diffraction efficiency at each wavelength is at its maximum is selected as the diffraction order, but a value with which the diffraction efficiency is not at its maximum may be used as the diffraction order.

The stair-like diffraction structure provided on the third region 151C is a periodic structure in which one cycle is composed of 4-level steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element 163 increases. The step height of the stair-like diffraction structure of the third region 151C is set such that the diffraction efficiency of +1st order diffracted light is at its maximum when the blue light of the wavelength λ1 is used and the diffraction efficiency of −1st order diffracted light is at its maximum when the red light of the wavelength λ2 is used. One cycle of the stair-like diffraction structure provided on the third region 151C does not necessarily have to be composed of 4-level steps and may be composed of steps other than 4-level steps. In addition, in the present embodiment, a value with which the diffraction efficiency at each wavelength is at its maximum is selected as the diffraction order, but a value with which the diffraction efficiency is not at its maximum may be used as the diffraction order.

The step height of the sawtooth-like diffraction structure provided on the outer region 151F is set such that the diffraction efficiency of +3rd order diffracted light is at its maximum when the blue light of the wavelength λ1 is used. The diffraction order having the maximum diffraction efficiency may be a diffraction order other than +3rd order. However, the outer region 151F is a region dedicated for BD, and thus preferably has an aperture limiting function for adjusting an effective NA, with respect to light of a wavelength other than the light for BD. In other words, it is desired that light of a wavelength other than the wavelength λ1, which is incident on the outer region 151F, does not contribute to a spot and does not return as stray light onto the photodetector 33. The stray light refers to light which is reflected by a surface of an optical disc, a recording surface of the optical disc, an optical component on an optical path, a lens surface, or the like and which influences the intensity of signal light on the photodetector.

4. Regarding Characteristic Portions

The objective lens element 163 according to the present embodiment satisfies the following condition formulas (1) and (2).

|A1−B1|<|A2−B2|  (1)

|B1|≧|B2|  (2)

Here,

A1 is the diffraction order at the first region to converge the light of the wavelength λ3 on the information recording surface,

B1 is the diffraction order at the first region to converge the light of the wavelength λ3 on the information recording surface,

A2 is the diffraction order at the second region to converge the light of the wavelength λ3 on the information recording surface, and

B2 is the diffraction order at the second region to converge the light of the wavelength λ1 on the information recording surface.

By selecting the diffraction order at the first region 131A and the diffraction order at the second region 131B such that the condition formulas (1) and (2) are satisfied, the width of each ring zone of the periodic structure of the second region 151B can be made larger than the width of each ring zone of the periodic structure of the first region 151A. As a result, the diffraction efficiency improves. The reason why the diffraction efficiency improves will be described below.

First, the working distances for BD and CD will be described. The working distance is the distance between the objective lens element 163 and a surface of an information storage medium.

When the working distance is shortened, there is the possibility that the objective lens element 163 and the information storage medium will be brought into contact with each other. However, in the case of BD, when the working distance is lengthened, the focal distance increases, and thus the diameter of the objective lens element has to be increased in order to obtain a desired numerical aperture. In addition, when the working distance is long, deterioration of performance caused by a manufacturing error is great. Thus, it is difficult to lengthen the working distance when BD is used.

Meanwhile, regarding CD, sufficient performance can be ensured even when the working distance is lengthened to some extent as compared to BD. Thus, the working distance when CD is used can be set so as to be long to some extent, in order to prevent the objective lens element 163 and the information storage medium (here, CD) from being brought into contact with each other.

In order to lengthen the working distance for CD, it is necessary to increase diffraction power.

In order to increase the diffraction power, it is necessary to shorten the cycle of the diffraction structure. However, when the cycle of the diffraction structure is shortened, the diffraction efficiency decreases. In particular, the diffraction efficiency of light for CD decreases. As a result, performance required for CD cannot be realized.

Thus, in the present embodiment, in order to prevent the diffraction efficiency of light of at least one wavelength (here, the diffraction efficiency of light for CD) from decreasing, the diffraction order for BD at the first region 151A is set to +2nd order, the diffraction order for CD at the first region 151A is set to −2nd order, the diffraction order for BD at the second region 151B is set to +2nd order, and the diffraction order for CD at the second region 151B is set to −3rd order.

As described above, in the present embodiment, the diffraction order for the light for BD at the second region 151B is made the same as the diffraction order for the light for BD at the first region 151A, and the absolute value of the diffraction order for the light for CD at the second region 151B is made higher than the absolute value of the diffraction order for the light for CD at the first region 151A. In other words, the difference between the diffraction order for BD and the diffraction order for CD at the second region 151B is made greater than the difference between the diffraction order for BD and the diffraction order for CD at the first region 151A.

When a difference in diffraction order is great, the angular difference between diffracted light for BD and diffracted light for CD also increases. In order to converge diffracted light for BD or diffracted light for CD, which has passed through the first region 151A and the second region 151B, to form a desired spot in a state where a difference in diffraction order is great, it is necessary to decrease the angular difference between the diffracted light for BD and the diffracted light for CD in the second region 151B. Thus, in order to decrease the angular difference between the diffracted light for BD and the diffracted light for DVD, the diffraction power of the second region 151B is decreased.

Since the diffraction power is decreased, the cycle of the diffraction structure can be widened. By widening the cycle of the diffraction structure, decrease of the diffraction efficiency can be prevented. This is because increase of the diffraction power can be suppressed by using diffracted light of a high order.

While the diffraction order of the light (the wavelength λ1) for BD at the first region 151A is +2nd and the diffraction order of the light (the wavelength λ3) for CD at the first region 151A is −2nd, the diffraction order of the light (the wavelength λ1) for BD at the second region 151B is +2nd and the diffraction order of the light (the wavelength λ3) for CD at the second region 151B is −3rd. The absolute value of the diffraction order of the light for CD is higher at the second region 151B than at the first region 151A, and thus the diffraction angle of the light for CD is higher at the second region 151B than at the first region 151A. However, in the case of BD, the diffraction orders at the first region 151A and the second region 151B are the same.

Since the difference between the diffraction orders of the light for BD and the light for CD is increased at the second region 151B compared to the first region 151A as described above, the diffraction power for ensuring the same working distance can be small. In other words, the interval of the periodic diffraction shape of the second region 151B is wider than the interval of the diffraction shape of the first region 151A. In the present embodiment, by providing such a configuration, the diffraction efficiency of the light for BD greatly improves.

In the second embodiment, the regions which contribute to formation of spots of light with the three wavelengths for BD, DVD, and CD have been described as an example. However, the second embodiment may be applied to a region which contributes to formation of spots of light with the two wavelengths for BD and DVD. In other words, where B1 is the diffraction order at the first region with respect to the light of the wavelength λ2 and B2 is the diffraction order at the second region with respect to the light of the wavelength λ2, it suffices that a diffraction order is selected such that the condition formulas (1) and (2) are satisfied.

In other words, the first region may be formed as a region which contributes to formation of spots of light with the three wavelengths for BD, DVD, and CD, each of the second region and the third region may be formed as a region which contributes to formation of spots of light with the two wavelengths for BD and DVD, and the outer region may be formed as a region dedicated for BD, which contributes to formation of a spot of only the light for BD. In this case, it suffices that each of the diffraction structures of the second region and the third region satisfies the condition formulas (1) and (2) in the first embodiment. By so doing, it is possible to improve the diffraction efficiency for either BD or DVD.

Third Embodiment

FIGS. 7A and 7B are optical path diagrams of an objective lens according to a third embodiment of the present invention. Specifically, FIG. 7A is an optical path diagram when DVD is used, and FIG. 7B is an optical path diagram when CD is used.

The objective lens element 183 according to the present embodiment is a BD/DVD/CD compatible lens. The objective lens element 183 can converge light of a wavelength λ1 for BD on an information recording surface through a base plate having a thickness t1 to form a spot thereon, can converge light of a wavelength λ2 for DVD on an information recording surface through a base plate having a thickness t2 to form a spot thereon, and can converge light of a wavelength λ3 for CD on an information recording surface through a base plate having a thickness t3 to form a spot thereon (λ1<λ2<λ3 and t1<t2<t3). Here, the objective lens element 183 is designed such that when the light for BD is used, a spherical aberration which occurs when a parallel light beam is incident on an incident surface thereof is small. In addition, the objective lens element 183 is designed such that: when the light for DVD is used, a spherical aberration which occurs when a converging light beam is incident on the incident surface is smaller than a spherical aberration which occurs when a parallel light beam of the same wavelength is incident on the incident surface; and when the light for CD is used, a spherical aberration which occurs when a diverging light beam is incident on the incident surface is smaller than a spherical aberration which occurs when a parallel light beam of the same wavelength is incident on the incident surface.

The objective lens element 183 according to the present embodiment satisfies the following conditions.

L1<0  (3)

L2>0  (4)

Here,

L1 is the distance from the incident surface of the objective lens element to an object point of a light source of the wavelength λ2, and

L2 is the distance from the incident surface of the objective lens element to an object point of a light source of the wavelength λ3.

It should be noted that the object point distance is set so as to be positive when the object point is on the light source side (the left side in FIGS. 7A and 7B) of the incident surface of the objective lens element 183, and is set so as to be negative when the object point is on the optical disc side (the right side in FIGS. 7A and 7B) of the incident surface of the objective lens element 183.

According to the present embodiment, while the optical performance when the light for BD is used is optimized, optical performance for DVD and CD can also be ensured. Thus, the three-wavelength compatible objective lens element 183 having excellent optical performance can be realized.

EXAMPLES

Hereinafter, Examples of the present invention will be described with construction data and specific values of diffraction efficiencies. It should be noted that in each Example, a surface to which an aspheric coefficient is provided indicates a refractive optical surface having an aspherical shape or a surface (e.g., a diffractive surface) having a refraction function equal to that of an aspheric surface. The surface shape of an aspheric surface is defined by the following formula.

$X = {\frac{C_{j}h^{2}}{1 + \sqrt{1 - {\left( {1 + k_{j}} \right)C_{j}^{2}h^{2}}}} + {\sum{A_{j,n}h^{n}}}}$

Here,

X is the distance from an on-the-aspheric-surface point at a height h relative to the optical axis to a tangential plane at the top of the aspheric surface,

h is the height relative to the optical axis,

C_(j) is the radius of curvature at the top of an aspheric surface of a j^(th) surface of a lens (C_(j)=1/R_(j)),

k_(j) is the conic constant of the j^(th) surface of the lens, and

A_(j,n) is the n^(th)-order aspheric constant of the j^(th) surface of the lens.

Further, a phase difference caused by a diffraction structure added to an optical surface is provided by the following formula.

φ(h)=MΣP _(j,m) h ^(2m)

Here,

φ(h) is a phase function,

h is the height relative to the optical axis,

P_(j,m) is the 2m^(th)-order phase function coefficient of the j^(th) surface of the lens, and

M is a diffraction order.

FIGS. 8 to 12 are partially enlarged views of diffraction structures of objective lens elements according to Examples 1 to 5, respectively. Specifically, FIGS. 8 to 12 each are an enlarged view of a compatible region composed of a first region and a second region. In FIGS. 8 to 12, a portion below a diffraction shape represented by a broken line is a lens material, and a portion above the diffraction shape is air.

Example 1

Example 1 corresponds to the first embodiment. The first surface of an objective lens element according to Example 1 is divided into a first region including a symmetry axis, a second region surrounding the first region, and an outer region surrounding the second region. A 4-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the first region of the first surface. A 4-level stair-like diffraction structure whose height monotonically increases step by step as distance from the optical axis of the objective lens element increases is provided on the second region. A sawtooth-like diffraction structure is provided on the outer region. The second surface is also divided into a first region and an outer region, and different aspheric surfaces are provided on these regions, respectively. The objective lens element according to Example 1 is a BD/DVD compatible lens. With regard to designed values for BD, the wavelength is 408 nm; the focal length is 1.30 mm; the numerical aperture (NA) is 0.86; and the protective layer thickness of an information storage medium is 0.1 mm. With regard to designed values for DVD, the wavelength is 660 nm; the focal length is 1.45 mm; the NA is 0.6; and the protective layer thickness of an information storage medium is 0.6 mm.

Tables 1 and 2 show construction data of the objective lens element according to Example 1.

TABLE 1 BD DVD Wavelength 0.408 0.660 Effective diameter 2.24 1.79 NA 0.86 0.60 Working distance (WD) 0.38 0.30 Disc thickness (DT) 0.10 0.60 Focal length 1.30 1.45 First surface,_ Inner region 1 −1 Diffraction order First surface, Middle region 2 −1 Diffraction order First surface, Outer region 3 — Diffraction order Object point (OP) ∞ 150 Radius of Surface curvature at No. the top Thickness Material Remarks 0 OP 1 0.865865 1.561992 n1 Inner region (Diffractive surface), Middle region (Diffractive surface), Outer region (Diffractive surface) 2 −1.383884 WD Inner region (Aspheric surface), Outer region (Aspheric surface) 3 ∞ DT disc Planar 4 ∞ Planar Wavelength 0.408 0.660 n1 1.52196 1.50413 disc 1.61642 1.57815

TABLE 2 Inner region First surface Diffractive surface Region 0 mm-0.86 mm Aspherical constant RD 0.86586496 k −0.65493979 A0 0 A2 0 A4 0.043157648 A6 0.022669249 A8 −0.011628554 A10 0.04337541 A12 −0.020193608 Phase function P2 −286.87093 P4 34.691426 P6 −35.053222 Middle region First surface Diffractive surface Region 0.86 mm-0.90 mm Aspherical constant RD 0.6889239 k −1.123762 A0 6.93E−02 A2 0 A4 −0.72506052 A6 −0.36650133 A8 1.2488416 A10 5.7418087 A12 1.2738183 A14 −39.026355 A16 45.308213 A18 8.1660937 A20 −37.137781 A22 15.526237 Phase function P2 −428.05758 P4 306.21925 P6 −144.05443 Outer region First surface Diffractive surface Region 0.90 mm-1.12 mm Aspherical constant RD 0.8865722 k −0.650895 A0 7.76E−03 A2 0 A4 0.035157518 A6 0.060338707 A8 0.021728949 A10 −0.04642263 A12 −0.006640622 A14 0.002299187 A16 0.01567928 A18 0.041621567 A20 −0.038273541 Phase function P2 −195.47933 P4 −107.2491 Inner region Second surface Aspheric surface Region 0 mm-0.51 mm Aspherical constant RD −1.383884 k −25.670907 A0 0 A2 0 A4 0.43509192 A6 −0.82598537 A8 −0.64638874 A10 5.2735825 A12 −6.8737179 Outer region Second surface Aspheric surface Region 0.51 mm-0.88 mm Aspherical constant RD −1.383884 k −33.488315 A0 −0.000255988 A2 0 A4 0.28103759 A6 −0.40400028 A8 −0.14767444 A10 0.68091898 A12 −0.039113439 A14 −1.4783633 A16 1.8259917 A18 −0.5551804 A20 −0.41580555 A22 0.26520865

Tables 3A-3E show ring zone cycles of the stair-like step structure provided on the first region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 3A Cycle [μm] Cycle [μm] First ring zone 147.67 First step 74.02 Second step 30.70 Third step 23.58 Fourth step 19.89 Second ring zone 61.64 First step 17.54 Second step 15.88 Third step 14.61 Fourth step 13.61 Third ring zone 47.47 First step 12.80 Second step 12.11 Third step 11.53 Fourth step 11.03 Fourth ring zone 40.14 First step 10.58 Second step 10.19 Third step 9.84 Fourth step 9.53 Fifth ring zone 35.47 First step 9.24 Second step 8.98 Third step 8.74 Fourth step 8.52 Sixth ring zone 32.15 First step 8.31 Second step 8.12 Third step 7.94 Fourth step 7.78 Seventh ring zone 29.64 First step 7.62 Second step 7.47 Third step 7.34 Fourth step 7.21 Eighth ring zone 27.64 First step 7.08 Second step 6.96 Third step 6.85 Fourth step 6.74

TABLE 3B Cycle [μm] Cycle [μm] Ninth ring zone 26.00 First step 6.64 Second step 6.55 Third step 6.45 Fourth step 6.36 Tenth ring zone 24.63 First step 6.28 Second step 6.20 Third step 6.12 Fourth step 6.04 Eleventh ring zone 23.45 First step 5.97 Second step 5.90 Third step 5.83 Fourth step 5.76 Twelfth ring zone 22.42 First step 5.70 Second step 5.64 Third step 5.58 Fourth step 5.52 Thirteenth ring zone 21.52 First step 5.46 Second step 5.41 Third step 5.35 Fourth step 5.30 Fourteenth ring zone 20.71 First step 5.25 Second step 5.20 Third step 5.15 Fourth step 5.10 Fifteenth ring zone 19.97 First step 5.06 Second step 5.01 Third step 4.97 Fourth step 4.93 Sixteenth ring zone 19.31 First step 4.89 Second step 4.85 Third step 4.81 Fourth step 4.77

TABLE 3C Cycle [μm] Cycle [μm] Seventeenth ring zone 18.70 First step 4.73 Second step 4.69 Third step 4.66 Fourth step 4.62 Eighteenth ring zone 18.13 First step 4.58 Second step 4.55 Third step 4.52 Fourth step 4.48 Nineteenth ring zone 17.61 First step 4.45 Second step 4.42 Third step 4.39 Fourth step 4.35 Twentieth ring zone 17.12 First step 4.32 Second step 4.29 Third step 4.26 Fourth step 4.23 Twenty-first ring zone 16.66 First step 4.21 Second step 4.18 Third step 4.15 Fourth step 4.12 Twenty-second ring zone 16.22 First step 4.10 Second step 4.07 Third step 4.04 Fourth step 4.02 Twenty-third ring zone 15.81 First step 3.99 Second step 3.97 Third step 3.94 Fourth step 3.92 Twenty-fourth ring zone 15.42 First step 3.89 Second step 3.87 Third step 3.84 Fourth step 3.82

TABLE 3D Cycle [μm] Cycle [μm] Twenty-fifth ring zone 15.05 First step 3.80 Second step 3.77 Third step 3.75 Fourth step 3.73 Twenty-sixth ring zone 14.70 First step 3.71 Second step 3.69 Third step 3.66 Fourth step 3.64 Twenty-seventh ring zone 14.36 First step 3.62 Second step 3.60 Third step 3.58 Fourth step 3.56 Twenty-eighth ring zone 14.04 First step 3.54 Second step 3.52 Third step 3.50 Fourth step 3.48 Twenty-ninth ring zone 13.73 First step 3.46 Second step 3.44 Third step 3.42 Fourth step 3.40 Thirtieth ring zone 13.43 First step 3.39 Second step 3.37 Third step 3.35 Fourth step 3.33 Thirty-first ring zone 13.14 First step 3.31 Second step 3.29 Third step 3.28 Fourth step 3.26 Thirty-second ring zone 12.86 First step 3.24 Second step 3.22 Third step 3.21 Fourth step 3.19

TABLE 3E Cycle [μm] Cycle [μm] Thirty-third ring zone 12.60 First step 3.17 Second step 3.16 Third step 3.14 Fourth step 3.12

On the first region of Example 1, one ring zone cycle is composed of consecutive 4-level stair-like steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 3A-3E indicate the width of a ring zone in a radial direction (in a direction perpendicular to the optical axis) as indicated by an arrow in FIG. 8. On the first region, a first ring zone, a second ring zone, a third ring zone, . . . , and a thirty-third ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 8. In each ring zone, the steps are referred to as a first step, a second step, a third step, and a fourth step in order from the optical axis side toward the outer periphery side.

Table 4 shows ring zone cycles of the stair-like step structure provided on the second region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 4 Cycle [μm] Cycle [μm] First ring zone 17.06 First step 4.30 Second step 4.28 Third step 4.25 Fourth step 4.22 Second ring zone 16.62 First step 4.20 Second step 4.17 Third step 4.14 Fourth step 4.11

On the second region of Example 1, one ring zone cycle is composed of consecutive 4-level stair-like steps whose height monotonically increases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Table 4 indicates the width of a ring zone in the radial direction (in the direction perpendicular to the optical axis) as indicated by an arrow in FIG. 8. On the second region, a first ring zone and a second ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 8. In each ring zone, the steps are referred to as a first step, a second step, a third step, and a fourth step in order from the optical axis side toward the outer periphery side.

Table 5 shows ring zone cycles of the sawtooth-like diffraction structure provided on the outer region of the first surface.

TABLE 5 Cycle [μm] First ring zone 40.40 Second ring zone 24.83 Third ring zone 23.62 Fourth ring zone 22.53 Fifth ring zone 21.55 Sixth ring zone 20.65 Seventh ring zone 19.84 Eighth ring zone 19.10 Ninth ring zone 18.41

On the outer region, a first ring zone, a second ring zone, a third ring zone, a fourth ring zone, . . . , a ninth ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element.

Tables 6A-6E show step heights of the stair-like diffraction structure provided on the first region of the first surface. In one cycle of the stair-like diffraction structure, the height of each of the first to third steps is set such that a phase difference of 1.25 wavelengths is provided to light of the designed wavelength for BD, and the height of the fourth step is set such that a phase difference of 3.75 wavelengths is provided in the opposite direction.

TABLE 6A Depth [μm] First ring zone First step 0.97848 Second step 0.97988 Third step 0.98128 Fourth step 2.94806 Second ring zone First step 0.98411 Second step 0.98554 Third step 0.98699 Fourth step 2.96531 Third ring zone First step 0.98990 Second step 0.99138 Third step 0.99286 Fourth step 2.98305 Fourth ring zone First step 0.99585 Second step 0.99738 Third step 0.99890 Fourth step 3.00131 Fifth ring zone First step 1.00198 Second step 1.00354 Third step 1.00511 Fourth step 3.02006 Sixth ring zone First step 1.00828 Second step 1.00988 Third step 1.01150 Fourth step 3.03938 Seventh ring zone First step 1.01476 Second step 1.01640 Third step 1.01806 Fourth step 3.05921 Eighth ring zone First step 1.02143 Second step 1.02311 Third step 1.02483 Fourth step 3.07965

TABLE 6B Depth [μm] Ninth ring zone First step 1.02828 Second step 1.03003 Third step 1.03178 Fourth step 3.10065 Tenth ring zone First step 1.03534 Second step 1.03713 Third step 1.03894 Fourth step 3.12229 Eleventh ring zone First step 1.04260 Second step 1.04444 Third step 1.04630 Fourth step 3.14453 Twelfth ring zone First step 1.05006 Second step 1.05198 Third step 1.05389 Fourth step 3.16744 Thirteenth ring zone First step 1.05776 Second step 1.05971 Third step 1.06169 Fourth step 3.19103 Fourteenth ring zone First step 1.06568 Second step 1.06770 Third step 1.06973 Fourth step 3.21533 Fifteenth ring zone First step 1.07384 Second step 1.07591 Third step 1.07800 Fourth step 3.24034 Sixteenth ring zone First step 1.08224 Second step 1.08438 Third step 1.08653 Fourth step 3.26610

TABLE 6C Depth [μm] Seventeenth ring zone First step 1.09089 Second step 1.09309 Third step 1.09530 Fourth step 3.29261 Eighteenth ring zone First step 1.09980 Second step 1.10206 Third step 1.10435 Fourth step 3.31999 Nineteenth ring zone First step 1.10898 Second step 1.11131 Third step 1.11368 Fourth step 3.34815 Twentieth ring zone First step 1.11844 Second step 1.12085 Third step 1.12329 Fourth step 3.37718 Twenty-first ring zone First step 1.12820 Second step 1.13068 Third step 1.13319 Fourth step 3.40710 Twenty-second ring zone First step 1.13825 Second step 1.14081 Third step 1.14339 Fourth step 3.43796 Twenty-third ring zone First step 1.14861 Second step 1.15125 Third step 1.15390 Fourth step 3.46976 Twenty-fourth ring zone First step 1.15929 Second step 1.16200 Third step 1.16474 Fourth step 3.50250

TABLE 6D Depth [μm] Twenty-fifth ring zone First step 1.17029 Second step 1.17309 Third step 1.17591 Fourth step 3.53629 Twenty-sixth ring zone First step 1.18163 Second step 1.18451 Third step 1.18741 Fourth step 3.57105 Twenty-seventh ring zone First step 1.19330 Second step 1.19628 Third step 1.19928 Fourth step 3.60686 Twenty-eighth ring zone First step 1.20533 Second step 1.20839 Third step 1.21148 Fourth step 3.64373 Twenty-ninth ring zone First step 1.21771 Second step 1.22086 Third step 1.22404 Fourth step 3.68171 Thirtieth ring zone First step 1.23045 Second step 1.23369 Third step 1.23696 Fourth step 3.72075 Thirty-first ring zone First step 1.24356 Second step 1.24689 Third step 1.25025 Fourth step 3.76088 Thirty-second ring zone First step 1.25704 Second step 1.26046 Third step 1.26391 Fourth step 3.80216

TABLE 6E Depth [μm] Thirty-third ring zone First step 1.27088 Second step 1.27440 Third step 1.27794

Table 7 shows step heights of the stair-like diffraction structure provided on the second region of the first surface. In one cycle of the stair-like diffraction structure, the height of each of the first to third steps is set such that a phase difference of 0.25 wavelength is provided to light of the designed wavelength for DVD, and the height of the fourth step is set such that a phase difference of 0.75 wavelength is provided in the opposite direction.

TABLE 7 Depth [μm] First ring zone First step 0.43228 Second step 0.43394 Third step 0.43562 Fourth step 1.31194 Second ring zone First step 0.43903 Second step 0.44076 Third step 0.44252 Fourth step 1.33292

Table 8 shows step heights of the sawtooth-like diffraction structure provided on the outer region of the first surface. The step heights of the sawtooth-like diffraction structure are set such that a phase difference of 3 wavelengths is provided to the light of the designed wavelength for BD, and +3rd order diffracted light is used.

TABLE 8 Depth [μm] First ring zone 3.36561 Second ring zone 3.45768 Third ring zone 3.54477 Fourth ring zone 3.61974 Fifth ring zone 3.67212 Sixth ring zone 3.68745 Seventh ring zone 3.64692 Eighth ring zone 3.52776 Ninth ring zone 3.30591

Table 9 shows diffraction efficiencies at the thirty-third ring zone of the first region and at the second ring zone of the second region. The second ring zone of the second region is an outermost region which contributes to formation of a spot of the light for DVD in the present example.

TABLE 9 Diffraction efficiency(%) BD Inner region First ring zone 80 Thirty-third ring zone 61 Middle region Second ring zone 29 DVD Inner region First ring zone 78 Thirty-third ring zone 58 Middle region Second ring zone 72

The ring zone cycle of the thirty-third ring zone of the first region is about 13 μm, and the diffraction efficiency of the light for DVD is about 58%. Meanwhile, the ring zone cycle of the first ring zone of the first region is about 148 μm, and the diffraction efficiency of the light for DVD is about 78%. Thus, the diffraction efficiency of the light for DVD at the thirty-third ring zone of the first region is much lower than the diffraction efficiency at the first ring zone. When the present invention is not applied, the diameter of a spot on a recording surface is increased with this diffraction efficiency, and recording/reproducing performance of DVD deteriorates.

In contrast, the ring zone cycle of the second ring zone of the second region is about 17 μm. The diffraction efficiency of the light for DVD at the second ring zone of the second region is about 72% and is greatly improved as compared to that at the thirty-third ring zone of the first region. Thus, enlargement of a beam spot formed when the light for DVD is incident is suppressed. As a result, the recording/reproducing performance improves.

Example 2

Example 2 corresponds to the second embodiment. The first surface of an objective lens element according to Example 2 is divided into a first region including a symmetry axis, a second region surrounding the first region, a third region surrounding the second region, and an outer region surrounding the third region. A 6-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the first region of the first surface. An 8-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the second region. A 4-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the third region. A sawtooth-like diffraction structure is provided on the outer region. The second surface is an aspheric surface. The objective lens element according to Example 2 is a BD/DVD/CD compatible lens. With regard to designed values for BD, the wavelength is 405 nm; the focal length is 1.20 mm; and the protective layer thickness of an information storage medium is 0.085 mm. With regard to designed values for DVD, the wavelength is 650 nm; the focal length is 1.45 mm; and the protective layer thickness of an information storage medium is 0.6 mm. With regard to designed values for CD, the wavelength is 780 nm; the focal length is 1.64 mm; and the protective layer thickness of an information storage medium is 1.2 mm.

Tables 10 and 11 show construction data of the objective lens element according to Example 2.

TABLE 10 BD DVD CD Wavelength 0.405 0.650 0.780 Effective diameter 1.66 1.64 1.66 Working distance (WD) 0.47 0.44 0.30 Disc thickness (DT) 0.085 0.60 1.20 Focal length 1.20 1.45 1.64 First surface, First region 2 −1 −2 Diffraction order First surface, Second region 2 −2 −3 Diffraction order First surface, Third region 1 −1 — Diffraction order First surface, Outer region 3 — — Diffraction order Object point (OP) ∞ ∞ 400 Radius of Surface curvature at No. the top Thickness Material Remarks 0 OP 1 0.80094682 1.16723 n1 First region (Diffractive surface), Second region (Diffractive surface), Third region (Diffractive surface), Outer region (Diffractive surface) 2 −2.36979 WD Aspheric surface 3 ∞ DT disc Planar 4 ∞ Planar Wavelength 0.405 0.650 0.780 n1 1.52550 1.50746 1.50385 disc 1.61913 1.57881 1.57180

TABLE 11 First region First surface Diffractive surface Region 0 mm-0.76 mm Aspherical constant RD 0.80094682 k −0.99630763 A0 0 A2 0 A4 0.15911155 A6 0.10260604 A8 0.012767725 A10 −1.9922639 A12 9.054756 A14 −14.670648 A16 8.6186121 Phase function P2 −307.57297 P4 −18.255432 P6 13.625204 Second region First surface Diffractive surface Region 0.76 mm-0.82 mm Aspherical constant RD 0.38100041 k −1.8508273 A0 −1.21E−01 A2 0 A4 −0.035003385 A6 0.99082251 A8 −1.8892425 A10 −2.4967727 A12 17.673196 A14 −25.890832 A16 12.211077 A18 0.7497486 Phase function P2 −291.36683 P4 −215.20791 P6 306.73161 Aspherical Second surface constant RD −2.36979 k 16.74851 A0 0 A2 0 A4 1.5488076 A6 −10.726282 A8 36.424214 A10 553.29212 A12 −7238.9707 A14 37431.492 A16 −93807.005 A18 94316.616

Tables 12A-12F show ring zone cycles of the stair-like step structure provided on the first region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 12A Cycle [μm] Cycle [μm] First ring zone 142.39 First step 58.34 Second step 24.16 Third step 18.53 Fourth step 15.62 Fifth step 13.76 Sixth step 12.43 Second ring zone 59.05 First step 11.43 Second step 10.64 Third step 9.99 Fourth step 9.44 Fifth step 8.98 Sixth step 8.58 Third ring zone 45.24 First step 8.22 Second step 7.91 Third step 7.63 Fourth step 7.38 Fifth step 7.15 Sixth step 6.94 Fourth ring zone 38.08 First step 6.75 Second step 6.57 Third step 6.41 Fourth step 6.26 Fifth step 6.11 Sixth step 5.98 Fifth ring zone 33.50 First step 5.86 Second step 5.74 Third step 5.63 Fourth step 5.52 Fifth step 5.42 Sixth step 5.33

TABLE 12B Cycle [μm] Cycle [μm] Sixth ring zone 30.25 First step 5.24 Second step 5.16 Third step 5.07 Fourth step 5.00 Fifth step 4.92 Sixth step 4.85 Seventh ring zone 27.78 First step 4.78 Second step 4.72 Third step 4.66 Fourth step 4.60 Fifth step 4.54 Sixth step 4.48 Eighth ring zone 25.83 First step 4.43 Second step 4.38 Third step 4.33 Fourth step 4.28 Fifth step 4.23 Sixth step 4.19 Ninth ring zone 24.23 First step 4.14 Second step 4.10 Third step 4.06 Fourth step 4.02 Fifth step 3.98 Sixth step 3.94 Tenth ring zone 22.90 First step 3.90 Second step 3.87 Third step 3.83 Fourth step 3.80 Fifth step 3.76 Sixth step 3.73

TABLE 12C Cycle [μm] Cycle [μm] Eleventh ring zone 21.76 First step 3.70 Second step 3.67 Third step 3.64 Fourth step 3.61 Fifth step 3.58 Sixth step 3.55 Twelfth ring zone 20.77 First step 3.53 Second step 3.50 Third step 3.47 Fourth step 3.45 Fifth step 3.42 Sixth step 3.40 Thirteenth ring zone 19.91 First step 3.38 Second step 3.35 Third step 3.33 Fourth step 3.31 Fifth step 3.28 Sixth step 3.26 Fourteenth ring zone 19.15 First step 3.24 Second step 3.22 Third step 3.20 Fourth step 3.18 Fifth step 3.16 Sixth step 3.14 Fifteenth ring zone 18.47 First step 3.12 Second step 3.10 Third step 3.09 Fourth step 3.07 Fifth step 3.05 Sixth step 3.03

TABLE 12D Cycle [μm] Cycle [μm] Sixteenth ring zone 17.85 First step 3.02 Second step 3.00 Third step 2.98 Fourth step 2.97 Fifth step 2.95 Sixth step 2.94 Seventeenth ring zone 17.30 First step 2.92 Second step 2.90 Third step 2.89 Fourth step 2.88 Fifth step 2.86 Sixth step 2.85 Eighteenth ring zone 16.79 First step 2.83 Second step 2.82 Third step 2.80 Fourth step 2.79 Fifth step 2.78 Sixth step 2.77 Nineteenth ring zone 16.33 First step 2.75 Second step 2.74 Third step 2.73 Fourth step 2.71 Fifth step 2.70 Sixth step 2.69 Twentieth ring zone 15.90 First step 2.68 Second step 2.67 Third step 2.66 Fourth step 2.64 Fifth step 2.63 Sixth step 2.62

TABLE 12E Cycle [μm] Cycle [μm] Twenty-first ring zone 15.51 First step 2.61 Second step 2.60 Third step 2.59 Fourth step 2.58 Fifth step 2.57 Sixth step 2.56 Twenty-second ring zone 15.15 First step 2.55 Second step 2.54 Third step 2.53 Fourth step 2.52 Fifth step 2.51 Sixth step 2.50 Twenty-third ring zone 14.81 First step 2.49 Second step 2.48 Third step 2.47 Fourth step 2.46 Fifth step 2.45 Sixth step 2.45 Twenty-fourth ring zone 14.49 First step 2.44 Second step 2.43 Third step 2.42 Fourth step 2.41 Fifth step 2.40 Sixth step 2.39 Twenty-fifth ring zone 14.20 First step 2.39 Second step 2.38 Third step 2.37 Fourth step 2.36 Fifth step 2.35 Sixth step 2.35

TABLE 12F Cycle [μm] Cycle [μm] Twenty-sixth ring zone 13.92 First step 2.34 Second step 2.33 Third step 2.32 Fourth step 2.32 Fifth step 2.31 Sixth step 2.30 Twenty-seventh ring zone 13.67 First step 2.30 Second step 2.29 Third step 2.28 Fourth step 2.27 Fifth step 2.27 Sixth step 2.26 Twenty-eighth ring zone 13.42 First step 2.25 Second step 2.25 Third step 2.24 Fourth step 2.23 Fifth step 2.23

On the first region of Example 2, one ring zone cycle is composed of consecutive 6-level stair-like steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 12A-12F indicate the width of a ring zone in a radial direction (in a direction perpendicular to the optical axis) as indicated by an arrow in FIG. 9. On the first region, a first ring zone, a second ring zone, a third ring zone, . . . , and a twenty-eighth ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 9. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and a sixth step in order from the optical axis side toward the outer periphery side.

Table 13 shows ring zone cycles of the stair-like step structure provided on the second region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 13 Cycle [μm] Cycle [μm] First ring zone 19.67 First step 2.25 Second step 2.26 Third step 2.28 Fourth step 2.30 Fifth step 2.31 Sixth step 2.33 Seventh step 2.35 Eighth step 2.37 Second ring zone 19.91 First step 2.40 Second step 2.42 Third step 2.44 Fourth step 2.47 Fifth step 2.50 Sixth step 2.53 Seventh step 2.56 Eighth step 2.59 Third ring zone 22.25 First step 2.63 Second step 2.67 Third step 2.71 Fourth step 2.75 Fifth step 2.80 Sixth step 2.85 Seventh step 2.90 Eighth step 2.96

On the second region of Example 2, one ring zone cycle is composed of consecutive 8-level stair-like steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Table 13 indicates the width of a ring zone in the radial direction (in the direction perpendicular to the optical axis) as indicated by an arrow in FIG. 9. On the second region, a first ring zone, a second ring zone, and a third ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 9. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and an eighth step in order from the optical axis side toward the outer periphery side.

Tables 14A-14F show step heights of the stair-like diffraction structure provided on the first region of Example 2. In one cycle of the stair-like diffraction structure, the height of each of the first to fifth steps is set such that a phase difference of 1.33 wavelengths is provided to light of the designed wavelength for BD, and the height of the sixth step is set such that a phase difference of 6.65 wavelengths is provided in the opposite direction.

TABLE 14A Depth [μm] First ring zone First step 1.02853 Second step 1.02972 Third step 1.03090 Fourth step 1.03210 Fifth step 1.03331 Sixth step 5.17257 Second ring zone First step 1.03574 Second step 1.03695 Third step 1.03818 Fourth step 1.03942 Fifth step 1.04066 Sixth step 5.20950 Third ring zone First step 1.04315 Second step 1.04442 Third step 1.04569 Fourth step 1.04695 Fifth step 1.04823 Sixth step 5.24755 Fourth ring zone First step 1.05079 Second step 1.05210 Third step 1.05339 Fourth step 1.05470 Fifth step 1.05602 Sixth step 5.28668 Fifth ring zone First step 1.05866 Second step 1.05999 Third step 1.06133 Fourth step 1.06268 Fifth step 1.06403 Sixth step 5.32693

TABLE 14B Depth [μm] Sixth ring zone First step 1.06675 Second step 1.06812 Third step 1.06949 Fourth step 1.07088 Fifth step 1.07227 Sixth step 5.36832 Seventh ring zone First step 1.07506 Second step 1.07648 Third step 1.07789 Fourth step 1.07932 Fifth step 1.08074 Sixth step 5.41085 Eighth ring zone First step 1.08362 Second step 1.08506 Third step 1.08651 Fourth step 1.08798 Fifth step 1.08945 Sixth step 5.45464 Ninth ring zone First step 1.09241 Second step 1.09389 Third step 1.09538 Fourth step 1.09689 Fifth step 1.09839 Sixth step 5.49956 Tenth ring zone First step 1.10143 Second step 1.10296 Third step 1.10451 Fourth step 1.10604 Fifth step 1.10760 Sixth step 5.54581

TABLE 14C Depth [μm] Eleventh ring zone First step 1.11074 Second step 1.11231 Third step 1.11389 Fourth step 1.11548 Fifth step 1.11708 Sixth step 5.59347 Twelfth ring zone First step 1.12031 Second step 1.12193 Third step 1.12357 Fourth step 1.12521 Fifth step 1.12686 Sixth step 5.64266 Thirteenth ring zone First step 1.13020 Second step 1.13188 Third step 1.13357 Fourth step 1.13528 Fifth step 1.13698 Sixth step 5.69351 Fourteenth ring zone First step 1.14043 Second step 1.14218 Third step 1.14393 Fourth step 1.14569 Fifth step 1.14746 Sixth step 5.74623 Fifteenth ring zone First step 1.15105 Second step 1.15286 Third step 1.15467 Fourth step 1.15651 Fifth step 1.15835 Sixth step 5.80108

TABLE 14D Depth [μm] Sixteenth ring zone First step 1.16208 Second step 1.16396 Third step 1.16586 Fourth step 1.16777 Fifth step 1.16969 Sixth step 5.85814 Seventeenth ring zone First step 1.17359 Second step 1.17555 Third step 1.17752 Fourth step 1.17952 Fifth step 1.18153 Sixth step 5.91772 Eighteenth ring zone First step 1.18558 Second step 1.18764 Third step 1.18972 Fourth step 1.19180 Fifth step 1.19390 Sixth step 5.98010 Nineteenth ring zone First step 1.19815 Second step 1.20030 Third step 1.20247 Fourth step 1.20466 Fifth step 1.20686 Sixth step 6.04542 Twentieth ring zone First step 1.21131 Second step 1.21358 Third step 1.21584 Fourth step 1.21814 Fifth step 1.22045 Sixth step 6.11394

TABLE 14E Depth [μm] Twenty-first ring zone First step 1.22513 Second step 1.22751 Third step 1.22991 Fourth step 1.23232 Fifth step 1.23474 Sixth step 6.18599 Twenty-second ring zone First step 1.23968 Second step 1.24218 Third step 1.24470 Fourth step 1.24725 Fifth step 1.24982 Sixth step 6.26203 Twenty-third ring zone First step 1.25502 Second step 1.25767 Third step 1.26034 Fourth step 1.26303 Fifth step 1.26575 Sixth step 6.34248 Twenty-fourth ring zone First step 1.27128 Second step 1.27408 Third step 1.27692 Fourth step 1.27980 Fifth step 1.28269 Sixth step 6.42813 Twenty-fifth ring zone First step 1.28860 Second step 1.29161 Third step 1.29465 Fourth step 1.29773 Fifth step 1.30085 Sixth step 6.52004

TABLE 14F Depth [μm] Twenty-sixth ring zone First step 1.30721 Second step 1.31046 Third step 1.31375 Fourth step 1.31708 Fifth step 1.32048 Sixth step 6.61961 Twenty-seventh ring zone First step 1.32741 Second step 1.33097 Third step 1.33459 Fourth step 1.33825 Fifth step 1.34200 Sixth step 6.72898 Twenty-eighth ring zone First step 1.34968 Second step 1.35362 Third step 1.35765 Fourth step 1.36175 Fifth step 1.36594

Table 15 shows step heights of the stair-like diffraction structure provided on the second region of Example 2. In one cycle of the stair-like diffraction structure, the height of each of the first to seventh steps is set such that a phase difference of 1.25 wavelengths is provided to the light of the designed wavelength for BD, and the height of the eighth step is set such that a phase difference of 8.75 wavelengths is provided in the opposite direction.

TABLE 15 Depth [μm] First ring zone First step 1.31640 Second step 1.32066 Third step 1.32509 Fourth step 1.32966 Fifth step 1.33443 Sixth step 1.33936 Seventh step 1.34451 Eighth step 9.44913 Second ring zone First step 1.35549 Second step 1.36134 Third step 1.36748 Fourth step 1.37393 Fifth step 1.38069 Sixth step 1.38783 Seventh step 1.39535 Eighth step 9.82310 Third ring zone First step 1.41174 Second step 1.42069 Third step 1.43023 Fourth step 1.44041 Fifth step 1.45131 Sixth step 1.46303 Seventh step 1.47563 Eighth step 10.42484

It should be noted that although not shown, the 4-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the third region of Example 2. Further, the sawtooth-like diffraction structure is provided on the outer region of Example 2.

Table 16 shows diffraction efficiencies at the twenty-eighth ring zone of the first region and at the third ring zone of the second region. The third ring zone of the second region is an outermost region which contributes to formation of a spot of light for CD in the present example.

TABLE 16 Diffraction efficiency (%) BD Inner region First ring zone 67 Twenty-ninth ring zone 44 Middle region Third ring zone 60 DVD Inner region First ring zone 71 Twenty-ninth ring zone 56 Middle region Third ring zone 34 CD Inner region First ring zone 65 Twenty-ninth ring zone 30 Middle region Third ring zone 19

The ring zone cycle of the twenty-eighth ring zone of the first region is about 13 μm, and the diffraction efficiency of the light for BD is about 44%. Meanwhile, the ring zone cycle of the first ring zone of the first region is about 142 μm, and the diffraction efficiency of the light for BD is about 67%. Thus, the diffraction efficiency of the light for BD at the twenty-eighth ring zone of the first region is much lower than the diffraction efficiency at the first ring zone. When the present invention is not applied, an amount of light in reproducing/recording on BD is insufficient with this diffraction efficiency.

In contrast, the ring zone cycle of the third ring zone of the second region is about 22 μm. The diffraction efficiency of the light for BD at the third ring zone of the second region is about 60% and is greatly improved as compared to the diffraction efficiency at the twenty-eighth ring zone of the first region. Thus, insufficiency of the light amount in reproducing/recording on BD is suppressed.

Example 3

The first surface of an objective lens element according to Example 3 is divided into a first region including a symmetry axis, a second region surrounding the first region, a third region surrounding the second region, and an outer region surrounding the third region. A 7-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the first region of the first surface. A 9-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the second region. A 4-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the third region. A sawtooth-like diffraction structure is provided on the outer region. The second surface is an aspheric surface. The objective lens element according to Example 3 is a BD/DVD/CD compatible lens. With regard to designed values for BD, the wavelength is 408 nm; the focal length is 1.30 mm; and the protective layer thickness of an information storage medium is 0.087 mm. With regard to designed values for DVD, the wavelength is 660 nm; the focal length is 1.57 mm; and the protective layer thickness of an information storage medium is 0.6 mm. With regard to designed values for CD, the wavelength is 785 nm; the focal length is 1.75 mm; and the protective layer thickness of an information storage medium is 1.2 mm.

Tables 17 and 18 show construction data of the objective lens element according to Example 3.

TABLE 17 BD DVD CD Wavelength 0.408 0.660 0.785 Effective diameter 1.66 1.66 1.66 Working distance (WD) 0.49 0.46 0.30 Disc thickness (DT) 0.087 0.60 1.20 Focal length 1.30 1.57 1.75 First surface, First region 1 −2 −3 Diffraction order First surface, Second region 1 −3 −4 Diffraction order First surface, Third region 1 −1 — Diffraction order First surface, _Outer region 3 — — Diffraction order Object point (OP) ∞ ∞ ∞ Radius of Surface curvature at No. the top Thickness Material Remarks 0 OP 1 0.80042572 1.284183 n1 First region (Diffractive surface), Second region (Diffractive surface), Third region (Diffractive surface), Outer region (Diffractive surface) 2 −2.757568 WD Aspheric surface 3 ∞ DT disc Planar 4 ∞ Planar Wavelength 0.408 0.660 0.785 n1 1.52505 1.50711 1.50374 disc 1.61805 1.57812 1.57160

TABLE 18 First region First surface Diffractive surface Region 0 mm-0.71 mm Aspherical constant RD 0.80042572 k −0.97591321 A0 0 A2 0 A4 0.20000627 A6 −1.0643006 A8 8.1610405 A10 −35.521826 A12 88.358799 A14 −115.97361 A16 62.150855 Phase function P2 −224.64389 P4 −50.652842 P6 −2.6251858 Second region First surface Diffractive surface Region 0.71 mm-0.83 mm Aspherical constant RD 0.84517215 k −0.68523888 A0 −8.41E−03 A2 0 A4 0.28575967 A6 −0.42240361 A8 1.5410588 A10 −4.7704736 A12 6.8216812 A14 −4.5550413 A16 1.3664987 Phase function P2 −226.34345 P4 −171.83969 P6 245.90644 Second surface Aspherical constant RD −2.757568 k 4.138653 A0 0 A2 0 A4 0.68975206 A6 −8.8967286 A8 82.669118 A10 −419.18394 A12 1083.2938 A14 −1248.8704 A16 480.15496

Tables 19A-19E show ring zone cycles of the stair-like step structure provided on the first region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 19A Cycle [μm] Cycle [μm] First ring zone 166.13 First step 63.18 Second step 26.13 Third step 20.02 Fourth step 16.86 Fifth step 14.83 Sixth step 13.39 Seventh step 12.30 Second ring zone 68.33 First step 11.43 Second step 10.72 Third step 10.13 Fourth step 9.62 Fifth step 9.18 Sixth step 8.79 Seventh step 8.45 Third ring zone 51.95 First step 8.14 Second step 7.87 Third step 7.61 Fourth step 7.38 Fifth step 7.17 Sixth step 6.98 Seventh step 6.80 Fourth ring zone 43.41 First step 6.63 Second step 6.47 Third step 6.32 Fourth step 6.19 Fifth step 6.06 Sixth step 5.93 Seventh step 5.82

TABLE 19B Cycle [μm] Cycle [μm] Fifth ring zone 37.91 First step 5.71 Second step 5.60 Third step 5.50 Fourth step 5.41 Fifth step 5.32 Sixth step 5.23 Seventh step 5.15 Sixth ring zone 33.99 First step 5.07 Second step 4.99 Third step 4.92 Fourth step 4.85 Fifth step 4.78 Sixth step 4.72 Seventh step 4.65 Seventh ring zone 30.99 First step 4.59 Second step 4.54 Third step 4.48 Fourth step 4.42 Fifth step 4.37 Sixth step 4.32 Seventh step 4.27 Eighth ring zone 28.61 First step 4.22 Second step 4.18 Third step 4.13 Fourth step 4.09 Fifth step 4.04 Sixth step 4.00 Seventh step 3.96

TABLE 19C Cycle [μm] Cycle [μm] Ninth ring zone 26.66 First step 3.92 Second step 3.88 Third step 3.84 Fourth step 3.81 Fifth step 3.77 Sixth step 3.74 Seventh step 3.70 Tenth ring zone 25.02 First step 3.67 Second step 3.64 Third step 3.60 Fourth step 3.57 Fifth step 3.54 Sixth step 3.51 Seventh step 3.48 Eleventh ring zone 23.61 First step 3.45 Second step 3.43 Third step 3.40 Fourth step 3.37 Fifth step 3.35 Sixth step 3.32 Seventh step 3.29 Twelfth ring zone 22.39 First step 3.27 Second step 3.25 Third step 3.22 Fourth step 3.20 Fifth step 3.17 Sixth step 3.15 Seventh step 3.13

TABLE 19D Cycle [μm] Cycle [μm] Thirteenth ring zone 21.32 First step 3.11 Second step 3.09 Third step 3.07 Fourth step 3.04 Fifth step 3.02 Sixth step 3.00 Seventh step 2.98 Fourteenth ring zone 20.36 First step 2.96 Second step 2.95 Third step 2.93 Fourth step 2.91 Fifth step 2.89 Sixth step 2.87 Seventh step 2.85 Fifteenth ring zone 19.51 First step 2.84 Second step 2.82 Third step 2.80 Fourth step 2.79 Fifth step 2.77 Sixth step 2.75 Seventh step 2.74 Sixteenth ring zone 18.73 First step 2.72 Second step 2.71 Third step 2.69 Fourth step 2.68 Fifth step 2.66 Sixth step 2.65 Seventh step 2.63

TABLE 19E Cycle [μm] Cycle [μm] Seventeenth ring zone 18.03 First step 2.62 Second step 2.60 Third step 2.59 Fourth step 2.58 Fifth step 2.56 Sixth step 2.55 Seventh step 2.54 Eighteenth ring zone 17.39 First step 2.52 Second step 2.51 Third step 2.50 Fourth step 2.48 Fifth step 2.47 Sixth step 2.46 Seventh step 2.45 Nineteenth ring zone 16.80 First step 2.43 Second step 2.42 Third step 2.41 Fourth step 2.40 Fifth step 2.39 Sixth step 2.38 Seventh step 2.37 Twentieth ring zone 16.25 First step 2.35 Second step 2.34 Third step 2.33 Fourth step 2.32 Fifth step 2.31 Sixth step 2.30 Seventh step 2.29

On the first region of Example 3, one ring zone cycle is composed of consecutive 7-level stair-like steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 19A-19E indicate the width of a ring zone in a radial direction (in a direction perpendicular to the optical axis) as indicated by an arrow in FIG. 10. On the second region, a first ring zone, a second ring zone, a third ring zone, . . . , and a twentieth ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 10. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and a seventh step in order from the optical axis side toward the outer periphery side.

Tables 20A and 20B show ring zone cycles of the stair-like step structure provided on the second region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 20A Cycle [μm] Cycle [μm] First ring zone 21.12 First step 2.32 Second step 2.32 Third step 2.33 Fourth step 2.34 Fifth step 2.35 Sixth step 2.35 Seventh step 2.36 Eighth step 2.37 Ninth step 2.38 Second ring zone 21.98 First step 2.39 Second step 2.40 Third step 2.41 Fourth step 2.43 Fifth step 2.44 Sixth step 2.45 Seventh step 2.47 Eighth step 2.48 Ninth step 2.50 Third ring zone 23.35 First step 2.51 Second step 2.53 Third step 2.55 Fourth step 2.57 Fifth step 2.59 Sixth step 2.61 Seventh step 2.63 Eighth step 2.66 Ninth step 2.68

TABLE 20B Cycle [μm] Cycle [μm] Fourth ring zone 25.62 First step 2.71 Second step 2.74 Third step 2.77 Fourth step 2.80 Fifth step 2.84 Sixth step 2.88 Seventh step 2.92 Eighth step 2.96 Ninth step 3.00 Fifth ring zone 29.92 First step 3.05 Second step 3.11 Third step 3.17 Fourth step 3.23 Fifth step 3.30 Sixth step 3.38 Seventh step 3.46 Eighth step 3.56 Ninth step 3.66

On the second region of Example 3, one ring zone cycle is composed of consecutive 9-level stair-like steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 20A and 20B indicate the width of a ring zone in the radial direction (in the direction perpendicular to the optical axis) as indicated by an arrow in FIG. 10. On the second region, a first ring zone, a second ring zone, a third ring zone, . . . , and a fifth ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 10. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and a ninth step in order from the optical axis side toward the outer periphery side.

Tables 21A-21E show step heights of the stair-like diffraction structure provided on the first region of Example 3. In one cycle of the stair-like diffraction structure, the height of each of the first to sixth steps is set such that a phase difference of 1.14 wavelengths is provided to light of the designed wavelength for BD, and the height of the seventh step is set such that a phase difference of 6.84 wavelengths is provided in the opposite direction.

TABLE 21A Depth [μm] First ring zone First step 0.88924 Second step 0.89029 Third step 0.89135 Fourth step 0.89241 Fifth step 0.89347 Sixth step 0.89453 Seventh step 5.37365 Second ring zone First step 0.89668 Second step 0.89776 Third step 0.89884 Fourth step 0.89993 Fifth step 0.90100 Sixth step 0.90210 Seventh step 5.41912 Third ring zone First step 0.90428 Second step 0.90538 Third step 0.90648 Fourth step 0.90758 Fifth step 0.90869 Sixth step 0.90978 Seventh step 5.46535 Fourth ring zone First step 0.91201 Second step 0.91312 Third step 0.91424 Fourth step 0.91536 Fifth step 0.91648 Sixth step 0.91761 Seventh step 5.51246

TABLE 21B Depth [μm] Fifth ring zone First step 0.91987 Second step 0.92101 Third step 0.92215 Fourth step 0.92329 Fifth step 0.92444 Sixth step 0.92558 Seventh step 5.56040 Sixth ring zone First step 0.92789 Second step 0.92904 Third step 0.93020 Fourth step 0.93136 Fifth step 0.93253 Sixth step 0.93369 Seventh step 5.60916 Seventh ring zone First step 0.93603 Second step 0.93720 Third step 0.93838 Fourth step 0.93956 Fifth step 0.94075 Sixth step 0.94192 Seventh step 5.65867 Eighth ring zone First step 0.94430 Second step 0.94550 Third step 0.94669 Fourth step 0.94789 Fifth step 0.94909 Sixth step 0.95029 Seventh step 5.70894

TABLE 21C Depth [μm] Ninth ring zone First step 0.95270 Second step 0.95391 Third step 0.95513 Fourth step 0.95634 Fifth step 0.95755 Sixth step 0.95877 Seventh step 5.75997 Tenth ring zone First step 0.96123 Second step 0.96245 Third step 0.96369 Fourth step 0.96492 Fifth step 0.96616 Sixth step 0.96740 Seventh step 5.81188 Eleventh ring zone First step 0.96989 Second step 0.97114 Third step 0.97240 Fourth step 0.97365 Fifth step 0.97491 Sixth step 0.97618 Seventh step 5.86462 Twelfth ring zone First step 0.97872 Second step 0.97999 Third step 0.98127 Fourth step 0.98255 Fifth step 0.98383 Sixth step 0.98511 Seventh step 5.91839

TABLE 21D Depth [μm] Thirteenth ring zone First step 0.98769 Second step 0.98899 Third step 0.99028 Fourth step 0.99159 Fifth step 0.99289 Sixth step 0.99419 Seventh step 5.97304 Fourteenth ring zone First step 0.99681 Second step 0.99812 Third step 0.99944 Fourth step 1.00075 Fifth step 1.00208 Sixth step 1.00339 Seventh step 6.02832 Fifteenth ring zone First step 1.00603 Second step 1.00736 Third step 1.00869 Fourth step 1.01001 Fifth step 1.01134 Sixth step 1.01268 Seventh step 6.08401 Sixteenth ring zone First step 1.01533 Second step 1.01666 Third step 1.01799 Fourth step 1.01933 Fifth step 1.02066 Sixth step 1.02200 Seventh step 6.14004

TABLE 21E Depth [μm] Seventeenth ring zone First step 1.02468 Second step 1.02603 Third step 1.02736 Fourth step 1.02871 Fifth step 1.03007 Sixth step 1.03143 Seventh step 6.19675 Eighteenth ring zone First step 1.03416 Second step 1.03555 Third step 1.03693 Fourth step 1.03832 Fifth step 1.03974 Sixth step 1.04116 Seventh step 6.25559 Nineteenth ring zone First step 1.04405 Second step 1.04552 Third step 1.04702 Fourth step 1.04854 Fifth step 1.05009 Sixth step 1.05165 Seventh step 6.31958 Twentieth ring zone First step 1.05490 Second step 1.05659 Third step 1.05830 Fourth step 1.06008 Fifth step 1.06190 Sixth step 1.06379

Tables 22A and 22B show step heights of the stair-like diffraction structure provided on the second region of Example 3. In one cycle of the stair-like diffraction structure, the height of each of the first to eighth steps is set such that a phase difference of 1.11 wavelengths is provided to the light of the designed wavelength for BD, and the height of the ninth step is set such that a phase difference of 8.88 wavelengths is provided in the opposite direction.

TABLE 22A Depth [μm] First ring zone First step 1.03439 Second step 1.03557 Third step 1.03676 Fourth step 1.03797 Fifth step 1.03919 Sixth step 1.04044 Seventh step 1.04170 Eighth step 1.04298 Ninth step 8.35422 Second ring zone First step 1.04560 Second step 1.04695 Third step 1.04832 Fourth step 1.04972 Fifth step 1.05114 Sixth step 1.05259 Seventh step 1.05408 Eighth step 1.05560 Ninth step 8.45731 Third ring zone First step 1.05875 Second step 1.06039 Third step 1.06208 Fourth step 1.06380 Fifth step 1.06559 Sixth step 1.06742 Seventh step 1.06932 Eighth step 1.07127 Ninth step 8.58643

TABLE 22B Depth [μm] Fourth ring zone First step 1.07540 Second step 1.07758 Third step 1.07984 Fourth step 1.08219 Fifth step 1.08465 Sixth step 1.08722 Seventh step 1.08990 Eighth step 1.09272 Ninth step 8.76536 Fifth ring zone First step 1.09878 Second step 1.10206 Third step 1.10554 Fourth step 1.10922 Fifth step 1.11314 Sixth step 1.11733 Seventh step 1.12181 Eighth step 1.12663 Ninth step 9.05467

It should be noted that although not shown, the 4-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the third region of Example 3. The sawtooth-like diffraction structure is provided on the outer region of Example 3.

Table 23 shows diffraction efficiencies at the twentieth ring zone of the first region and at the fifth ring zone of the second region. The fifth ring zone of the second region is an outermost region which contributes to formation of a spot of light for CD in the present example.

TABLE 23 Diffraction efficiency(%) BD Inner region First ring zone 89 Twentieth ring zone 43 Middle region Fifth ring zone 58 DVD Inner region First ring zone 62 Twentieth ring zone 26 Middle region Fifth ring zone 12 CD Inner region First ring zone 50 Twentieth ring zone 21 Middle region Fifth ring zone 6

The ring zone cycle of the twentieth ring zone of the first region is about 16 μm, and the diffraction efficiency of the light for BD is about 43%. Meanwhile, the ring zone cycle of the first ring zone of the first region is about 166 μm, and the diffraction efficiency of the light for BD at the first ring zone is about 89%. Thus, the diffraction efficiency of the light for BD at the twentieth ring zone of the first region is much lower than the diffraction efficiency at the first ring zone. When the present invention is not applied, an amount of light in reproducing/recording on BD is insufficient with this diffraction efficiency. In contrast, the ring zone cycle of the fifth ring zone of the second region is about 13 μm. The diffraction efficiency of the light for BD at the fifth ring zone of the second region is about 58% and is greatly improved as compared to the diffraction efficiency at the twentieth ring zone of the first region. Thus, insufficiency of the light amount in reproducing/recording on BD is suppressed.

Example 4

The first surface of an objective lens element according to Example 4 is divided into a first region including a symmetry axis, a second region surrounding the first region, and an outer region surrounding the second region. A 6-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the first region of the first surface. A 6-level stair-like diffraction structure whose height monotonically increases step by step as distance from the optical axis of the objective lens element increases is provided on the second region. A sawtooth-like diffraction structure is provided on the outer region. The second surface is provided with an aspheric surface. The objective lens element according to Example 4 is a BD/DVD compatible lens. With regard to designed values for BD, the wavelength is 408 nm; the focal length is 1.22 mm; and the protective layer thickness of an information storage medium is 0.1 mm. With regard to designed values for DVD, the wavelength is 660 nm; the focal length is 1.40 mm; and the protective layer thickness of an information storage medium is 0.6 mm.

Tables 24 and 25 show construction data of the objective lens element according to Example 4.

TABLE 24 BD DVD Wavelength 0.408 0.660 Effective diameter 1.68 1.68 Working distance (WD) 0.40 0.40 Disc thickness (DT) 0.10 0.60 Focal length 1.22 1.40 First surface, First region 2 −1 Diffraction order First surface, Second region 1 −3 Diffraction order First surface, _Outer region 3 — Diffraction order Object point (OP) ∞ ∞ Radius of Surface curvature at No. the top Thickness Material Remarks 0 OP 1 0.81915814 1.296403 n1 First region (Diffractive surface), Second region (Diffractive surface), Outer region (Diffractive surface) 2 −2.029534 WD Aspheric surface 3 ∞ DT disc Planar 4 ∞ Planar Wavelength 0.408 0.660 n1 1.52505 1.50711 disc 1.61642 1.57815

TABLE 25 First region First surface Diffractive surface Region 0 mm-0.69 mm Aspherical constant RD 0.81915814 k −1.0331387 A0 0 A2 0 A4 0.15889713 A6 −0.026375804 A8 0.54253097 A10 −1.7713649 A12 3.6778599 A14 −3.8852706 A16 1.7582532 Phase function P2 −334.63934 P4 −2.2724443 P6 −12.706397 Second region First surface Diffractive surface Region 0.69 mm-0.84 mm Aspherical constant RD 0.30439226 k −1.5749807 A0 −1.81E−01 A2 0 A4 −0.22148822 A6 0.81109812 A8 −1.9054705 A10 −1.9178654 A12 18.412031 A14 −27.313249 A16 12.802057 Phase function P2 −720.17443 P4 1117.5096 P6 −677.1287 Second surface Aspherical constant RD −2.029534 k 13.40262 A0 0 A2 0 A4 1.7105509 A6 −14.232857 A8 145.08836 A10 −740.00426 A12 2202.1175 A14 −16617.021 A16 143605.41 A18 −530438.03 A20 685600.44

Tables 26A-26F show ring zone cycles of the stair-like step structure provided on the first region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 26A Cycle [μm] Cycle [μm] First ring zone 136.29 First step 55.94 Second step 23.17 Third step 17.78 Fourth step 14.99 Fifth step 13.20 Sixth step 11.94 Second ring zone 56.73 First step 10.98 Second step 10.22 Third step 9.59 Fourth step 9.07 Fifth step 8.63 Sixth step 8.25 Third ring zone 43.52 First step 7.91 Second step 7.61 Third step 7.34 Fourth step 7.10 Fifth step 6.88 Sixth step 6.68 Fourth ring zone 36.68 First step 6.50 Second step 6.33 Third step 6.17 Fourth step 6.03 Fifth step 5.89 Sixth step 5.76 Fifth ring zone 32.30 First step 5.64 Second step 5.53 Third step 5.43 Fourth step 5.33 Fifth step 5.23 Sixth step 5.14

TABLE 26B Cycle [μm] Cycle [μm] Sixth ring zone 29.18 First step 5.06 Second step 4.97 Third step 4.90 Fourth step 4.82 Fifth step 4.75 Sixth step 4.68 Seventh ring zone 26.82 First step 4.62 Second step 4.56 Third step 4.50 Fourth step 4.44 Fifth step 4.38 Sixth step 4.33 Eighth ring zone 24.95 First step 4.28 Second step 4.23 Third step 4.18 Fourth step 4.13 Fifth step 4.09 Sixth step 4.04 Ninth ring zone 23.42 First step 4.00 Second step 3.96 Third step 3.92 Fourth step 3.88 Fifth step 3.84 Sixth step 3.81 Tenth ring zone 22.13 First step 3.77 Second step 3.74 Third step 3.70 Fourth step 3.67 Fifth step 3.64 Sixth step 3.61

TABLE 26C Cycle [μm] Cycle [μm] Eleventh ring zone 21.03 First step 3.58 Second step 3.55 Third step 3.52 Fourth step 3.49 Fifth step 3.46 Sixth step 3.44 Twelfth ring zone 20.08 First step 3.41 Second step 3.38 Third step 3.36 Fourth step 3.33 Fifth step 3.31 Sixth step 3.28 Thirteenth ring zone 19.24 First step 3.26 Second step 3.24 Third step 3.22 Fourth step 3.19 Fifth step 3.17 Sixth step 3.15 Fourteenth ring zone 18.49 First step 3.13 Second step 3.11 Third step 3.09 Fourth step 3.07 Fifth step 3.05 Sixth step 3.03 Fifteenth ring zone 17.82 First step 3.01 Second step 3.00 Third step 2.98 Fourth step 2.96 Fifth step 2.94 Sixth step 2.93

TABLE 26D Cycle [μm] Cycle [μm] Sixteenth ring zone 17.22 First step 2.91 Second step 2.89 Third step 2.88 Fourth step 2.86 Fifth step 2.85 Sixth step 2.83 Seventeenth ring zone 16.67 First step 2.81 Second step 2.80 Third step 2.78 Fourth step 2.77 Fifth step 2.76 Sixth step 2.74 Eighteenth ring zone 16.16 First step 2.73 Second step 2.71 Third step 2.70 Fourth step 2.69 Fifth step 2.67 Sixth step 2.66 Nineteenth ring zone 15.70 First step 2.65 Second step 2.63 Third step 2.62 Fourth step 2.61 Fifth step 2.60 Sixth step 2.59 Twentieth ring zone 15.27 First step 2.57 Second step 2.56 Third step 2.55 Fourth step 2.54 Fifth step 2.53 Sixth step 2.52

TABLE 26E Cycle [μm] Cycle [μm] Twenty-first ring zone 14.87 First step 2.51 Second step 2.49 Third step 2.48 Fourth step 2.47 Fifth step 2.46 Sixth step 2.45 Twenty-second ring zone 14.50 First step 2.44 Second step 2.43 Third step 2.42 Fourth step 2.41 Fifth step 2.40 Sixth step 2.39 Twenty-third ring zone 14.15 First step 2.38 Second step 2.37 Third step 2.36 Fourth step 2.35 Fifth step 2.34 Sixth step 2.34 Twenty-fourth ring zone 13.82 First step 2.33 Second step 2.32 Third step 2.31 Fourth step 2.30 Fifth step 2.29 Sixth step 2.28 Twenty-fifth ring zone 13.52 First step 2.27 Second step 2.27 Third step 2.26 Fourth step 2.25 Fifth step 2.24 Sixth step 2.23

TABLE 26F Cycle [μm] Cycle [μm] Twenty-sixth ring zone 13.23 First step 2.22 Second step 2.22 Third step 2.21 Fourth step 2.20 Fifth step 2.19 Sixth step 2.18

On the first region of Example 4, one ring zone cycle is composed of consecutive 6-level stair-like steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 26A-26F indicate the width of a ring zone in a radial direction (in a direction perpendicular to the optical axis) as indicated by an arrow in FIG. 11. On the first region, a first ring zone, a second ring zone, a third ring zone, . . . , and a twenty-sixth ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 11. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and a sixth step in order from the optical axis side toward the outer periphery side.

Tables 27A and 27B show ring zone cycles of the stair-like step structure provided on the second region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 27A Cycle [μm] Cycle [μm] First ring zone 20.01 First step 3.29 Second step 3.31 Third step 3.33 Fourth step 3.35 Fifth step 3.36 Sixth step 3.37 Second ring zone 20.29 First step 3.38 Second step 3.38 Third step 3.39 Fourth step 3.39 Fifth step 3.38 Sixth step 3.38 Third ring zone 19.97 First step 3.37 Second step 3.36 Third step 3.34 Fourth step 3.32 Fifth step 3.30 Sixth step 3.28 Fourth ring zone 19.04 First step 3.25 Second step 3.22 Third step 3.19 Fourth step 3.16 Fifth step 3.13 Sixth step 3.09 Fifth ring zone 17.69 First step 3.05 Second step 3.01 Third step 2.97 Fourth step 2.93 Fifth step 2.89 Sixth step 2.84

TABLE 27B Cycle [μm] Cycle [μm] Sixth ring zone 16.14 First step 2.80 Second step 2.76 Third step 2.71 Fourth step 2.67 Fifth step 2.62 Sixth step 2.58 Seventh ring zone 14.61 First step 2.54 Second step 2.50 Third step 2.45 Fourth step 2.41 Fifth step 2.37 Sixth step 2.33

On the second region of Example 4, one ring zone cycle is composed of consecutive 6-level stair-like steps whose height monotonically increases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 27A and 27B indicate the width of a ring zone in the radial direction (in the direction perpendicular to the optical axis) as indicated by an arrow in FIG. 11. On the second region, a first ring zone, a second ring zone, a third ring zone, . . . , and a seventh ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 11. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and a sixth step in order from the optical axis side toward the outer periphery side.

Tables 28A-28F show step heights of the stair-like diffraction structure provided on the first region of Example 4. In one cycle of the stair-like diffraction structure, the height of each of the first to fifth steps is set such that a phase difference of 1.33 wavelengths is provided to light of the designed wavelength for BD, and the height of the sixth step is set such that a phase difference of 6.65 wavelengths is provided in the opposite direction.

TABLE 28A Depth [μm] First ring zone First step 1.03458 Second step 1.03566 Third step 1.03674 Fourth step 1.03783 Fifth step 1.03892 Sixth step 5.20003 Second ring zone First step 1.04111 Second step 1.04221 Third step 1.04332 Fourth step 1.04444 Fifth step 1.04555 Sixth step 5.23335 Third ring zone First step 1.04780 Second step 1.04893 Third step 1.05006 Fourth step 1.05121 Fifth step 1.05235 Sixth step 5.26747 Fourth ring zone First step 1.05465 Second step 1.05581 Third step 1.05698 Fourth step 1.05813 Fifth step 1.05932 Sixth step 5.30244 Fifth ring zone First step 1.06167 Second step 1.06286 Third step 1.06405 Fourth step 1.06525 Fifth step 1.06645 Sixth step 5.33829

TABLE 28B Depth [μm] Sixth ring zone First step 1.06887 Second step 1.07009 Third step 1.07132 Fourth step 1.07254 Fifth step 1.07378 Sixth step 5.37506 Seventh ring zone First step 1.07625 Second step 1.07750 Third step 1.07876 Fourth step 1.08001 Fifth step 1.08129 Sixth step 5.41277 Eighth ring zone First step 1.08383 Second step 1.08511 Third step 1.08640 Fourth step 1.08769 Fifth step 1.08899 Sixth step 5.45147 Ninth ring zone First step 1.09161 Second step 1.09293 Third step 1.09424 Fourth step 1.09557 Fifth step 1.09690 Sixth step 5.49124 Tenth ring zone First step 1.09959 Second step 1.10095 Third step 1.10230 Fourth step 1.10366 Fifth step 1.10503 Sixth step 5.53207

TABLE 28C Depth [μm] Eleventh ring zone First step 1.10780 Second step 1.10918 Third step 1.11058 Fourth step 1.11197 Fifth step 1.11338 Sixth step 5.57403 Twelfth ring zone First step 1.11623 Second step 1.11765 Third step 1.11909 Fourth step 1.12053 Fifth step 1.12197 Sixth step 5.61719 Thirteenth ring zone First step 1.12490 Second step 1.12636 Third step 1.12784 Fourth step 1.12933 Fifth step 1.13082 Sixth step 5.66161 Fourteenth ring zone First step 1.13383 Second step 1.13534 Third step 1.13686 Fourth step 1.13839 Fifth step 1.13992 Sixth step 5.70736 Fifteenth ring zone First step 1.14302 Second step 1.14457 Third step 1.14614 Fourth step 1.14772 Fifth step 1.14931 Sixth step 5.75444

TABLE 28D Depth [μm] Sixteenth ring zone First step 1.15250 Second step 1.15411 Third step 1.15572 Fourth step 1.15734 Fifth step 1.15898 Sixth step 5.80312 Seventeenth ring zone First step 1.16227 Second step 1.16394 Third step 1.16560 Fourth step 1.16729 Fifth step 1.16898 Sixth step 5.85333 Eighteenth ring zone First step 1.17238 Second step 1.17410 Third step 1.17581 Fourth step 1.17756 Fifth step 1.17930 Sixth step 5.90527 Nineteenth ring zone First step 1.18282 Second step 1.18460 Third step 1.18639 Fourth step 1.18818 Fifth step 1.18999 Sixth step 5.95907 Twentieth ring zone First step 1.19364 Second step 1.19548 Third step 1.19733 Fourth step 1.19919 Fifth step 1.20107 Sixth step 6.01479

TABLE 28E Depth [μm] Twenty-first ring zone First step 1.20485 Second step 1.20676 Third step 1.20868 Fourth step 1.21062 Fifth step 1.21256 Sixth step 6.07258 Twenty-second ring zone First step 1.21648 Second step 1.21848 Third step 1.22047 Fourth step 1.22248 Fifth step 1.22450 Sixth step 6.13270 Twenty-third ring zone First step 1.22859 Second step 1.23065 Third step 1.23274 Fourth step 1.23483 Fifth step 1.23693 Sixth step 6.19527 Twenty-fourth ring zone First step 1.24118 Second step 1.24334 Third step 1.24551 Fourth step 1.24769 Fifth step 1.24988 Sixth step 6.26044 Twenty-fifth ring zone First step 1.25432 Second step 1.25657 Third step 1.25883 Fourth step 1.26111 Fifth step 1.26339 Sixth step 6.32854

TABLE 28F Depth [μm] Twenty-sixth ring zone First step 1.26804 Second step 1.27039 Third step 1.27276 Fourth step 1.27514 Fifth step 1.27754

Tables 29A and 29B show step heights of the stair-like diffraction structure provided on the second region of Example 4. In one cycle of the stair-like diffraction structure, the height of each of the first to fifth steps is set such that a phase difference of 0.84 wavelength is provided to the light of the designed wavelength for BD, and the height of the sixth step is set such that a phase difference of 4.20 wavelengths is provided in the opposite direction.

TABLE 29A Depth [μm] First ring zone First step 0.81238 Second step 0.81451 Third step 0.81673 Fourth step 0.81903 Fifth step 0.82142 Sixth step 4.11949 Second ring zone First step 0.82647 Second step 0.82912 Third step 0.83186 Fourth step 0.83468 Fifth step 0.83760 Sixth step 4.20298 Third ring zone First step 0.84367 Second step 0.84683 Third step 0.85006 Fourth step 0.85337 Fifth step 0.85676 Sixth step 4.30105 Fourth ring zone First step 0.86373 Second step 0.86732 Third step 0.87096 Fourth step 0.87467 Fifth step 0.87842 Sixth step 4.41118 Fifth ring zone First step 0.88611 Second step 0.89002 Third step 0.89399 Fourth step 0.89799 Fifth step 0.90205 Sixth step 4.53079

TABLE 29B Depth [μm] Sixth ring zone First step 0.91030 Second step 0.91449 Third step 0.91873 Fourth step 0.92301 Fifth step 0.92734 Sixth step 4.65856 Seventh ring zone First step 0.93614 Second step 0.94061 Third step 0.94513 Fourth step 0.94971 Fifth step 0.95434 Sixth step 4.79518

It should be noted that although not shown, the sawtooth-like diffraction structure is provided on the outer region of Example 4.

Table 30 shows diffraction efficiencies at the twenty-sixth ring zone of the first region and at the eighth ring zone of the second region. The eighth ring zone of the second region is an outermost region which contributes to formation of a spot of light for DVD in the present example.

TABLE 30 Diffraction efficiency (%) BD Inner region First ring zone 67 Twenty-sixth ring zone 46 Middle region Eighth ring zone 63 DVD Inner region First ring zone 75 Twenty-sixth ring zone 54 Middle region Eighth ring zone 14

The ring zone cycle of the twenty-sixth ring zone of the first region is about 13 μm, and the diffraction efficiency of the light for BD is about 46%. Meanwhile, the ring zone cycle of the first ring zone of the first region is about 136 μm, and the diffraction efficiency of the light for BD is about 67%. Thus, the diffraction efficiency of the light for BD at the twenty-sixth ring zone of the first region is much lower than the diffraction efficiency at the first ring zone. When the present invention is not applied, an amount of light in reproducing/recording on BD is insufficient with this diffraction efficiency.

In contrast, the ring zone cycle of the eighth ring zone of the second region is about 13 μm. The diffraction efficiency of the light for BD at the eighth ring zone of the second region is about 63% and is greatly improved as compared to the diffraction efficiency at the twenty-sixth ring zone of the first region. Thus, insufficiency of the light amount in reproducing/recording on BD is suppressed.

Example 5

The first surface of an objective lens element according to Example 5 is divided into a first region including a symmetry axis, a second region surrounding the first region, and an outer region surrounding the second region. An 8-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the first region of the first surface. A 7-level stair-like diffraction structure whose height monotonically increases step by step as distance from the optical axis of the objective lens element increases is provided on the second region. A sawtooth-like diffraction structure is provided on the outer region. The second surface is provided with an aspheric surface. The objective lens element according to Example 4 is a BD/DVD compatible lens. With regard to designed values for BD, the wavelength is 408 nm; the focal length is 1.09 mm; and the protective layer thickness of an information storage medium is 0.1 mm. With regard to designed values for DVD, the wavelength is 660 nm; the focal length is 1.32 mm; and the protective layer thickness of an information storage medium is 0.6 mm.

Tables 31 and 32 show construction data of the objective lens element according to Example 5.

TABLE 31 BD DVD Wavelength 0.408 0.660 Effective diameter 1.68 1.68 Working distance (WD) 0.40 0.40 Disc thickness (DT) 0.10 0.60 Focal length 1.09 1.32 First surface, First 2 −2 region Diffraction order First surface, Second 5 −1 region Diffraction order First surface,_Outer 3 — region Diffraction order Object point (OP) ∞ ∞ Radius of curvature at Surface No. the top Thickness Material Remarks 0 OP 1 0.72399814 1.125319 n1 First region (Diffractive surface), Second region (Diffractive surface), Outer region (Diffractive surface) 2 −1.738506 WD Aspheric surface 3 ∞ DT disc Planar 4 ∞ Planar Wavelength 0.408 0.660 n1 1.52505 1.50711 disc 1.61642 1.57815

TABLE 32 First region Second region First surface Diffractive surface First surface Diffractive surface Second surface Aspherical constant Region 0 mm-0.69 mm Region 0.69 mm-0.84 mm RD −1.738506 Aspherical constant Aspherical constant k 8.591035 RD 0.72399814 RD 0.15483052 A0 0 k −0.80565617 k −1.4090207 A2 0 A0 0 A0 −2.39E−01 A4 2.1245151 A2 0 A2 0 A6 −7.4983864 A4 0.2220808 A4 −1.0390761 A8 −66.676749 A6 −0.54716594 A6 0.25086182 A10 1288.8438 A8 3.0481241 A8 −0.018007854 A12 −5781.1044 A10 −7.4996866 A10 2.3606036 A14 −13127.483 A12 7.6042347 A12 16.318267 A16 196387.57 A14 2.8548542 A14 −44.689687 A18 −611177.23 A16 −7.5452063 A16 29.696786 A20 639839.55 Phase function Phase function P2 −247.8751 P2 −490.42048 P4 30.793671 P4 646.10183 P6 −97.513681 P6 −342.89035

Tables 33A-33E shows ring zone cycles of the stair-like step structure provided on the first region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 33A Cycle [μm] Cycle [μm] First ring zone 158.94 First step 56.30 Second step 23.34 Third step 17.92 Fourth step 15.11 Fifth step 13.32 Sixth step 12.05 Seventh step 11.09 Eighth step 10.32 Second ring zone 66.32 First step 9.70 Second step 9.18 Third step 8.73 Fourth step 8.35 Fifth step 8.01 Sixth step 7.71 Seventh step 7.44 Eighth step 7.20 Third ring zone 51.00 First step 6.98 Second step 6.78 Third step 6.59 Fourth step 6.42 Fifth step 6.27 Sixth step 6.12 Seventh step 5.98 Eighth step 5.86 Fourth ring zone 43.04 First step 5.74 Second step 5.62 Third step 5.52 Fourth step 5.41 Fifth step 5.32 Sixth step 5.23 Seventh step 5.14 Eighth step 5.06

TABLE 33B Cycle [μm] Cycle [μm] Fifth ring zone 37.90 First step 4.98 Second step 4.91 Third step 4.83 Fourth step 4.76 Fifth step 4.70 Sixth step 4.63 Seventh step 4.57 Eighth step 4.51 Sixth ring zone 34.21 First step 4.46 Second step 4.40 Third step 4.35 Fourth step 4.30 Fifth step 4.25 Sixth step 4.20 Seventh step 4.15 Eighth step 4.11 Seventh ring zone 31.36 First step 4.06 Second step 4.02 Third step 3.98 Fourth step 3.94 Fifth step 3.90 Sixth step 3.86 Seventh step 3.82 Eighth step 3.79 Eighth ring zone 29.07 First step 3.75 Second step 3.72 Third step 3.68 Fourth step 3.65 Fifth step 3.62 Sixth step 3.58 Seventh step 3.55 Eighth step 3.52

TABLE 33C Cycle [μm] Cycle [μm] Ninth ring zone 27.15 First step 3.49 Second step 3.46 Third step 3.43 Fourth step 3.41 Fifth step 3.38 Sixth step 3.35 Seventh step 3.33 Eighth step 3.30 Tenth ring zone 25.51 First step 3.27 Second step 3.25 Third step 3.22 Fourth step 3.20 Fifth step 3.18 Sixth step 3.15 Seventh step 3.13 Eighth step 3.11 Eleventh ring zone 24.08 First step 3.08 Second step 3.06 Third step 3.04 Fourth step 3.02 Fifth step 3.00 Sixth step 2.98 Seventh step 2.96 Eighth step 2.94 Twelfth ring zone 22.80 First step 2.92 Second step 2.90 Third step 2.88 Fourth step 2.86 Fifth step 2.84 Sixth step 2.82 Seventh step 2.80 Eighth step 2.79

TABLE 33D Cycle [μm] Cycle [μm] Thirteenth ring zone 21.66 First step 2.77 Second step 2.75 Third step 2.73 Fourth step 2.72 Fifth step 2.70 Sixth step 2.68 Seventh step 2.67 Eighth step 2.65 Fourteenth ring zone 20.62 First step 2.63 Second step 2.62 Third step 2.60 Fourth step 2.59 Fifth step 2.57 Sixth step 2.55 Seventh step 2.54 Eighth step 2.52 Fifteenth ring zone 19.67 First step 2.51 Second step 2.49 Third step 2.48 Fourth step 2.47 Fifth step 2.45 Sixth step 2.44 Seventh step 2.42 Eighth step 2.41 Sixteenth ring zone 18.80 First step 2.40 Second step 2.38 Third step 2.37 Fourth step 2.36 Fifth step 2.34 Sixth step 2.33 Seventh step 2.32 Eighth step 2.30

TABLE 33E Cycle [μm] Cycle [μm] Seventeenth ring zone 17.99 First step 2.29 Second step 2.28 Third step 2.27 Fourth step 2.25 Fifth step 2.24 Sixth step 2.23 Seventh step 2.22 Eighth step 2.21 Eighteenth ring zone 17.24 First step 2.20 Second step 2.18 Third step 2.17 Fourth step 2.16 Fifth step 2.15 Sixth step 2.14 Seventh step 2.13 Eighth step 2.12 Nineteenth ring zone 16.54 First step 2.10 Second step 2.09 Third step 2.08 Fourth step 2.07 Fifth step 2.06 Sixth step 2.05 Seventh step 2.04 Eighth step 2.03 Twentieth ring zone 15.89 First step 2.02 Second step 2.01 Third step 2.00 Fourth step 1.99 Fifth step 1.98 Sixth step 1.97 Seventh step 1.96 Eighth step 1.95

On the first region of Example 5, one ring zone cycle is composed of consecutive 8-level stair-like steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 33A-33E indicate the width of a ring zone in a radial direction (in a direction perpendicular to the optical axis) as indicated by an arrow in FIG. 12. On the first region, a first ring zone, a second ring zone, a third ring zone, . . . , and a twentieth ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 12. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and an eighth step in order from the optical axis side toward the outer periphery side.

Tables 34A and 34B show ring zone cycles of the stair-like step structure provided on the second region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 34A Cycle [μm] Cycle [μm] First ring zone 22.81 First step 3.78 Second step 3.12 Third step 3.14 Fourth step 3.16 Fifth step 3.18 Sixth step 3.20 Seventh step 3.22 Second ring zone 23.06 First step 3.24 Second step 3.26 Third step 3.28 Fourth step 3.30 Fifth step 3.31 Sixth step 3.33 Seventh step 3.34 Third ring zone 23.64 First step 3.35 Second step 3.36 Third step 3.37 Fourth step 3.38 Fifth step 3.39 Sixth step 3.39 Seventh step 3.39 Fourth ring zone 23.64 First step 3.39 Second step 3.39 Third step 3.39 Fourth step 3.38 Fifth step 3.37 Sixth step 3.36 Seventh step 3.35

TABLE 34B Cycle [μm] Cycle [μm] Fifth ring zone 22.92 First step 3.33 Second step 3.32 Third step 3.30 Fourth step 3.28 Fifth step 3.26 Sixth step 3.23 Seventh step 3.21

On the second region of Example 5, one ring zone cycle is composed of consecutive 7-level stair-like steps whose height monotonically increases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 34A and 34B indicate the width of a ring zone in the radial direction (in the direction perpendicular to the optical axis) as indicated by an arrow in FIG. 12. On the second region, a first ring zone, a second ring zone, a third ring zone, . . . , and a fifth ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 12. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and a seventh step in order from the optical axis side toward the outer periphery side.

Tables 35A-35E show step heights of the stair-like diffraction structure provided on the first region of Example 5. In one cycle of the stair-like diffraction structure, the height of each of the first to seventh steps is set such that a phase difference of 1.25 wavelengths is provided to light of the designed wavelength for BD, and the height of the eighth step is set such that a phase difference of 8.75 wavelengths is provided in the opposite direction.

TABLE 35A Depth [μm] First ring zone First step 0.97255 Second step 0.97376 Third step 0.97499 Fourth step 0.97621 Fifth step 0.97746 Sixth step 0.97871 Seventh step 0.97996 Eighth step 6.86866 Second ring zone First step 0.98251 Second step 0.98380 Third step 0.98509 Fourth step 0.98639 Fifth step 0.98770 Sixth step 0.98901 Seventh step 0.99034 Eighth step 6.94173 Third ring zone First step 0.99301 Second step 0.99436 Third step 0.99573 Fourth step 0.99709 Fifth step 0.99846 Sixth step 0.99985 Seventh step 1.00124 Eighth step 7.01846 Fourth ring zone First step 1.00404 Second step 1.00545 Third step 1.00688 Fourth step 1.00830 Fifth step 1.00974 Sixth step 1.01119 Seventh step 1.01265 Eighth step 7.09879

TABLE 35B Depth [μm] Fifth ring zone First step 1.01559 Second step 1.01706 Third step 1.01855 Fourth step 1.02005 Fifth step 1.02156 Sixth step 1.02308 Seventh step 1.02460 Eighth step 7.18296 Sixth ring zone First step 1.02768 Second step 1.02923 Third step 1.03079 Fourth step 1.03236 Fifth step 1.03394 Sixth step 1.03553 Seventh step 1.03713 Eighth step 7.27116 Seventh ring zone First step 1.04035 Second step 1.04198 Third step 1.04361 Fourth step 1.04526 Fifth step 1.04691 Sixth step 1.04858 Seventh step 1.05025 Eighth step 7.36356 Eighth ring zone First step 1.05364 Second step 1.05534 Third step 1.05705 Fourth step 1.05878 Fifth step 1.06050 Sixth step 1.06225 Seventh step 1.06400 Eighth step 7.46034

TABLE 35C Depth [μm] Ninth ring zone First step 1.06753 Second step 1.06931 Third step 1.07110 Fourth step 1.07290 Fifth step 1.07471 Sixth step 1.07654 Seventh step 1.07838 Eighth step 7.56149 Tenth ring zone First step 1.08206 Second step 1.08393 Third step 1.08580 Fourth step 1.08769 Fifth step 1.08958 Sixth step 1.09149 Seventh step 1.09340 Eighth step 7.66728 Eleventh ring zone First step 1.09726 Second step 1.09921 Third step 1.10116 Fourth step 1.10314 Fifth step 1.10511 Sixth step 1.10710 Seventh step 1.10911 Eighth step 7.77788 Twelfth ring zone First step 1.11315 Second step 1.11519 Third step 1.11724 Fourth step 1.11930 Fifth step 1.12138 Sixth step 1.12345 Seventh step 1.12555 Eighth step 7.89364

TABLE 35D Depth [μm] Thirteenth ring zone First step 1.12979 Second step 1.13193 Third step 1.13408 Fourth step 1.13624 Fifth step 1.13841 Sixth step 1.14060 Seventh step 1.14280 Eighth step 8.01509 Fourteenth ring zone First step 1.14724 Second step 1.14949 Third step 1.15175 Fourth step 1.15401 Fifth step 1.15630 Sixth step 1.15860 Seventh step 1.16091 Eighth step 8.14275 Fifteenth ring zone First step 1.16559 Second step 1.16795 Third step 1.17033 Fourth step 1.17271 Fifth step 1.17511 Sixth step 1.17754 Seventh step 1.17998 Eighth step 8.27689 Sixteenth ring zone First step 1.18489 Second step 1.18736 Third step 1.18986 Fourth step 1.19236 Fifth step 1.19489 Sixth step 1.19743 Seventh step 1.19999 Eighth step 8.41785

TABLE 35E Depth [μm] Seventeenth ring zone First step 1.20514 Second step 1.20774 Third step 1.21034 Fourth step 1.21296 Fifth step 1.21560 Sixth step 1.21825 Seventh step 1.22093 Eighth step 8.56520 Eighteenth ring zone First step 1.22629 Second step 1.22898 Third step 1.23169 Fourth step 1.23441 Fifth step 1.23714 Sixth step 1.23988 Seventh step 1.24263 Eighth step 8.71763 Nineteenth ring zone First step 1.24814 Second step 1.25090 Third step 1.25368 Fourth step 1.25645 Fifth step 1.25923 Sixth step 1.26201 Seventh step 1.26479 Eighth step 8.87303 Twentieth ring zone First step 1.27035 Second step 1.27313 Third step 1.27590 Fourth step 1.27866 Fifth step 1.28141 Sixth step 1.28416 Seventh step 1.28690

Tables 36A and 36B show step heights of the stair-like diffraction structure provided on the second region of Example 5. In one cycle of the stair-like diffraction structure, the height of each of the first to sixth steps is set such that a phase difference of 0.26 wavelength is provided to the light of the designed wavelength for BD, and the height of the seventh step is set such that a phase difference of 1.56 wavelengths is provided in the opposite direction.

TABLE 36A Depth [μm] First ring zone First step 0.26920 Second step 0.27021 Third step 0.27127 Fourth step 0.27238 Fifth step 0.27353 Sixth step 0.27473 Seventh step 1.65591 Second ring zone First step 0.27730 Second step 0.27867 Third step 0.28011 Fourth step 0.28161 Fifth step 0.28319 Sixth step 0.28484 Seventh step 1.71949 Third ring zone First step 0.28841 Second step 0.29034 Third step 0.29238 Fourth step 0.29453 Fifth step 0.29681 Sixth step 0.29923 Seventh step 1.81075 Fourth ring zone First step 0.30452 Second step 0.30743 Third step 0.31054 Fourth step 0.31385 Fifth step 0.31740 Sixth step 0.32120 Seventh step 1.95168

TABLE 36B Depth [μm] Fifth ring zone First step 0.32965 Second step 0.33435 Third step 0.33939 Fourth step 0.34481 Fifth step 0.35064 Sixth step 0.35689 Seventh step 2.18174

It should be noted that although not shown, the sawtooth-like diffraction structure is provided on the outer region of Example 5.

Table 37 shows diffraction efficiencies at the twentieth ring zone of the first region and at the sixth ring zone of the second region. The sixth ring zone of the second region is an outermost region which contributes to formation of a spot of light for DVD in the present example.

TABLE 37 Diffractive efficiency (%) BD Inner region First ring zone 77 Twentieth ring zone 46 Middle region Sixth ring zone 9 DVD Inner region First ring zone 75 Twentieth ring zone 22 Middle region Sixth ring zone 85

The ring zone cycle of the twentieth ring zone of the first region is about 16 μm, and the diffraction efficiency of the light for DVD is about 22%. Meanwhile, the ring zone cycle of the first ring zone of the first region is about 159 μm, and the diffraction efficiency of the light for DVD is about 75%. Thus, the diffraction efficiency of the light for DVD at the twentieth ring zone of the first region is much lower than the diffraction efficiency at the first ring zone. When the present invention is not applied, the diameter of a spot on a recording surface is increased with this diffraction efficiency, and recording/reproducing performance of DVD deteriorates.

In contrast, the ring zone cycle of the sixth ring zone of the second region is about 22 μm. The diffraction efficiency of the light for DVD at the sixth ring zone of the second region is about 85% and is greatly improved as compared to that at the twentieth ring zone of the first region. Thus, enlargement of a beam spot formed when the light for DVD is incident is suppressed. As a result, the recording/reproducing performance improves.

Table 38 shows the relationship between diffraction orders of the objective lens elements according to Examples 1 to 5.

TABLE 38 1 2 3 4 5 BD- BD- BD- BD- BD- BD- BD- Example DVD DVD CD DVD CD DVD DVD A1 1 −1 −2 −2 −3 −1 2 B1 −1 2 2 1 1 2 −2 A2 2 −2 −3 −3 −4 −3 5 B2 −1 2 2 1 1 1 −1 |A1-B1| 2 3 4 3 4 3 4 |A2-B2| 3 4 5 4 5 4 6 |B1| 1 2 2 1 1 2 2 |B2| 1 2 2 1 1 1 1

FIGS. 13 and 14 are partially enlarged views of diffraction structures of objective lens elements according to Examples 6 and 7, respectively. Specifically, FIGS. 13 and 14 each are an enlarged view of a compatible region composed of a first region and a second region. In FIGS. 13 and 14, a portion below a diffraction shape represented by a broken line is a lens material, and a portion above the diffraction shape is air.

Example 6

Example 6 corresponds to the third embodiment. The first surface of an objective lens element according to Example 2 is divided into a first region including a symmetry axis, a second region surrounding the first region, a third region surrounding the second region, and an outer region surrounding the third region. A 6-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the first region of the first surface. An 8-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the second region. A 4-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the third region. A sawtooth-like diffraction structure is provided on the outer region. The second surface is an aspheric surface. The objective lens element according to Example 6 is a BD/DVD/CD compatible lens. With regard to designed values for BD, the wavelength is 405 nm; the focal length is 1.20 mm; and the protective layer thickness of an information storage medium is 0.085 mm. With regard to designed values for DVD, the wavelength is 650 nm; the focal length is 1.45 mm; and the protective layer thickness of an information storage medium is 0.6 mm. With regard to designed values for CD, the wavelength is 780 nm; the focal length is 1.64 mm; and the protective layer thickness of an information storage medium is 1.2 mm.

Tables 39 and 40 show construction data of the objective lens element according to Example 6.

TABLE 39 BD DVD CD Wavelength 0.405 0.650 0.780 Effective diameter 1.66 1.66 1.66 Working distance (WD) 0.47 0.44 0.30 Disc thickness (DT) 0.085 0.60 1.20 Focal length 1.2 1.45 1.64 First surface, First region 2 −1 −2 Diffraction order First surface, Second region 2 −2 −3 Diffraction order First surface, Third region 1 −1 — Diffraction order First surface, _Outer region 3 — — Diffraction order Object point (OP) ∞ −200 100 Radius of Surface curvature at No. the top Thickness Material Remarks 0 OP 1 0.80094682 1.16723 n1 First region (Diffractive surface), Second region (Diffractive surface), Third region (Diffractive surface), Outer region (Diffractive surface) 2 −2.36979 WD Aspheric surface 3 ∞ DT disc Planar 4 ∞ Planar Wavelength 0.405 0.650 0.780 n1 1.52550 1.50746 1.50385 disc 1.61913 1.57881 1.57180

TABLE 40 First region First surface Diffractive surface Region 0 mm-0.76 mm Aspherical constant RD 0.79379153 k −1.0089037 A0 0 A2 0 A4 0.15630796 A6 0.1234095 A8 −0.041797152 A10 −1.9732875 A12 9.3786807 A14 −15.409691 A16 9.1687136 Phase function P2 −302.57753 P4 −39.744514 P6 45.905067 Second Region First surface Diffractive surface Region 0.76 mm-0.82 mm Aspherical constant RD 0.37514459 k −1.7682624 A0 −0.13107122 A2 0 A4 −0.016040955 A6 0.97078969 A8 −1.9579984 A10 −2.5798109 A12 17.700268 A14 −25.617042 A16 12.626725 A18 0.12252176 Phase function P2 −328.02751 P4 −89.723276 P6 209.39281 Second surface Aspherical constant RD −2.433225 k 18.18902 A0 0 A2 0 A4 1.458337 A6 −10.079282 A8 32.941344 A10 561.91403 A12 −7183.1577 A14 37242.998 A16 −94611.808 A18 97317.354

Tables 41A-41F show ring zone cycles of the stair-like step structure provided on the first region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 41A Cycle [μm] Cycle [μm] First ring zone 143.91 First step 58.82 Second step 24.34 Third step 18.67 Fourth step 15.73 Fifth step 13.85 Sixth step 12.51 Second ring 59.36 First step 11.50 zone Second step 10.70 Third step 10.04 Fourth step 9.49 Fifth step 9.02 Sixth step 8.61 Third ring zone 45.39 First step 8.26 Second step 7.94 Third step 7.66 Fourth step 7.40 Fifth step 7.17 Sixth step 6.96 Fourth ring 38.15 First step 6.77 zone Second step 6.59 Third step 6.42 Fourth step 6.27 Fifth step 6.12 Sixth step 5.99 Fifth ring zone 33.52 First step 5.86 Second step 5.74 Third step 5.63 Fourth step 5.53 Fifth step 5.43 Sixth step 5.33

TABLE 41B Cycle [μm] Cycle [μm] Sixth ring zone 30.23 First step 5.24 Second step 5.15 Third step 5.07 Fourth step 4.99 Fifth step 4.92 Sixth step 4.85 Seventh ring 27.74 First step 4.78 zone Second step 4.71 Third step 4.65 Fourth step 4.59 Fifth step 4.53 Sixth step 4.48 Eighth ring 25.78 First step 4.42 zone Second step 4.37 Third step 4.32 Fourth step 4.27 Fifth step 4.22 Sixth step 4.18 Ninth ring zone 24.18 First step 4.13 Second step 4.09 Third step 4.05 Fourth step 4.01 Fifth step 3.97 Sixth step 3.93 Tenth ring zone 22.84 First step 3.89 Second step 3.86 Third step 3.82 Fourth step 3.79 Fifth step 3.76 Sixth step 3.72

TABLE 41C Cycle [μm] Cycle [μm] Eleventh ring zone 21.71 First step 3.69 Second step 3.66 Third step 3.63 Fourth step 3.60 Fifth step 3.57 Sixth step 3.55 Twelfth ring zone 20.73 First step 3.52 Second step 3.49 Third step 3.47 Fourth step 3.44 Fifth step 3.42 Sixth step 3.39 Thirteenth ring zone 19.88 First step 3.37 Second step 3.35 Third step 3.32 Fourth step 3.30 Fifth step 3.28 Sixth step 3.26 Fourteenth ring zone 19.13 First step 3.24 Second step 3.22 Third step 3.20 Fourth step 3.18 Fifth step 3.16 Sixth step 3.14 Fifteenth ring zone 18.46 First step 3.12 Second step 3.10 Third step 3.09 Fourth step 3.07 Fifth step 3.05 Sixth step 3.03

TABLE 41D Cycle [μm] Cycle [μm] Sixteenth ring zone 17.87 First step 3.02 Second step 3.00 Third step 2.99 Fourth step 2.97 Fifth step 2.95 Sixth step 2.94 Seventeenth ring zone 17.34 First step 2.92 Second step 2.91 Third step 2.90 Fourth step 2.88 Fifth step 2.87 Sixth step 2.85 Eighteenth ring zone 16.85 First step 2.84 Second step 2.83 Third step 2.82 Fourth step 2.80 Fifth step 2.79 Sixth step 2.78 Nineteenth ring zone 16.42 First step 2.77 Second step 2.75 Third step 2.74 Fourth step 2.73 Fifth step 2.72 Sixth step 2.71 Twentieth ring zone 16.02 First step 2.70 Second step 2.69 Third step 2.68 Fourth step 2.66 Fifth step 2.65 Sixth step 2.64

TABLE 41E Cycle [μm] Cycle [μm] Twenty-first ring zone 15.66 First step 2.63 Second step 2.62 Third step 2.61 Fourth step 2.60 Fifth step 2.60 Sixth step 2.59 Twenty-second ring zone 15.33 First step 2.58 Second step 2.57 Third step 2.56 Fourth step 2.55 Fifth step 2.54 Sixth step 2.53 Twenty-third ring zone 15.02 First step 2.52 Second step 2.52 Third step 2.51 Fourth step 2.50 Fifth step 2.49 Sixth step 2.48 Twenty-fourth ring zone 14.75 First step 2.48 Second step 2.47 Third step 2.46 Fourth step 2.45 Fifth step 2.45 Sixth step 2.44 Twenty-fifth ring zone 14.49 First step 2.43 Second step 2.43 Third step 2.42 Fourth step 2.41 Fifth step 2.40 Sixth step 2.40

TABLE 41F Cycle [μm] Cycle [μm] Twenty-sixth ring zone 14.26 First step 2.39 Second step 2.39 Third step 2.38 Fourth step 2.37 Fifth step 2.37 Sixth step 2.36 Twenty-seventh ring zone 14.04 First step 2.35 Second step 2.35 Third step 2.34 Fourth step 2.34 Fifth step 2.33 Sixth step 2.33 Twenty-eighth ring zone 13.85 First step 2.32 Second step 2.32 Third step 2.31 Fourth step 2.30 Fifth step 2.30 Sixth step 2.29

On the first region of Example 6, one ring zone cycle is composed of consecutive 6-level stair-like steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 41A-41F indicate the width of a ring zone in a radial direction (in a direction perpendicular to the optical axis) as indicated by an arrow in FIG. 13. On the first region, a first ring zone, a second ring zone, a third ring zone, . . . , and a twenty-eighth ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 13. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and a sixth step in order from the optical axis side toward the outer periphery side.

Table 42 shows ring zone cycles of the stair-like step structure provided on the second region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 42 Cycle [μm] Cycle [μm] First ring zone 22.55 First step 2.25 Second step 2.26 Third step 2.28 Fourth step 2.30 Fifth step 2.31 Sixth step 2.33 Seventh step 2.35 Eighth step 2.37 Second ring 21.15 First step 2.40 zone Second step 2.42 Third step 2.44 Fourth step 2.47 Fifth step 2.50 Sixth step 2.53 Seventh step 2.56 Eighth step 2.59

On the second region of Example 6, one ring zone cycle is composed of consecutive 8-level stair-like steps whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Table 42 indicates the width of a ring zone in the radial direction (in the direction perpendicular to the optical axis) as indicated by an arrow in FIG. 13. On the second region, a first ring zone and a second ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 13. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and an eighth step in order from the optical axis side toward the outer periphery side.

Tables 43A-43F show step heights of the stair-like diffraction structure provided on the first region of Example 6. In one cycle of the stair-like diffraction structure, the height of each of the first to fifth steps is set such that a phase difference of 1.33 wavelengths is provided to light of the designed wavelength for BD, and the height of the sixth step is set such that a phase difference of 6.65 wavelengths is provided in the opposite direction.

TABLE 43A Depth [μm] First ring zone First step 1.02856 Second step 1.02978 Third step 1.03101 Fourth step 1.03224 Fifth step 1.03347 Sixth step 5.17357 Second ring zone First step 1.03597 Second step 1.03722 Third step 1.03849 Fourth step 1.03974 Fifth step 1.04102 Sixth step 5.21143 Third ring zone First step 1.04358 Second step 1.04486 Third step 1.04615 Fourth step 1.04746 Fifth step 1.04875 Sixth step 5.25035 Fourth ring zone First step 1.05138 Second step 1.05271 Third step 1.05403 Fourth step 1.05536 Fifth step 1.05671 Sixth step 5.29028 Fifth ring zone First step 1.05940 Second step 1.06076 Third step 1.06213 Fourth step 1.06349 Fifth step 1.06488 Sixth step 5.33127

TABLE 43B Depth [μm] Sixth ring zone First step 1.06764 Second step 1.06904 Third step 1.07044 Fourth step 1.07185 Fifth step 1.07326 Sixth step 5.37339 Seventh ring zone First step 1.07610 Second step 1.07753 Third step 1.07897 Fourth step 1.08041 Fifth step 1.08186 Sixth step 5.41658 Eighth ring zone First step 1.08478 Second step 1.08625 Third step 1.08773 Fourth step 1.08921 Fifth step 1.09070 Sixth step 5.46097 Ninth ring zone First step 1.09369 Second step 1.09519 Third step 1.09671 Fourth step 1.09823 Fifth step 1.09976 Sixth step 5.50649 Tenth ring zone First step 1.10283 Second step 1.10439 Third step 1.10594 Fourth step 1.10751 Fifth step 1.10908 Sixth step 5.55328

TABLE 43C Depth [μm] Eleventh ring zone First step 1.11224 Second step 1.11384 Third step 1.11544 Fourth step 1.11704 Fifth step 1.11867 Sixth step 5.60147 Twelfth ring zone First step 1.12193 Second step 1.12357 Third step 1.12523 Fourth step 1.12688 Fifth step 1.12856 Sixth step 5.65119 Thirteenth ring zone First step 1.13192 Second step 1.13362 Third step 1.13533 Fourth step 1.13705 Fifth step 1.13878 Sixth step 5.70257 Fourteenth ring zone First step 1.14226 Second step 1.14402 Third step 1.14579 Fourth step 1.14758 Fifth step 1.14938 Sixth step 5.75589 Fifteenth ring zone First step 1.15301 Second step 1.15483 Third step 1.15667 Fourth step 1.15852 Fifth step 1.16039 Sixth step 5.81135

TABLE 43D Depth [μm] Sixteenth ring zone First step 1.16416 Second step 1.16607 Third step 1.16799 Fourth step 1.16993 Fifth step 1.17188 Sixth step 5.86920 Seventeenth ring zone First step 1.17581 Second step 1.17781 Third step 1.17981 Fourth step 1.18184 Fifth step 1.18388 Sixth step 5.92965 Eighteenth ring zone First step 1.18801 Second step 1.19009 Third step 1.19220 Fourth step 1.19431 Fifth step 1.19645 Sixth step 5.99303 Nineteenth ring zone First step 1.20078 Second step 1.20297 Third step 1.20518 Fourth step 1.20740 Fifth step 1.20966 Sixth step 6.05962 Twentieth ring zone First step 1.21420 Second step 1.21651 Third step 1.21884 Fourth step 1.22119 Fifth step 1.22356 Sixth step 6.12973

TABLE 43E Depth [μm] Twenty-first ring zone First step 1.22836 Second step 1.23079 Third step 1.23325 Fourth step 1.23573 Fifth step 1.23822 Sixth step 6.20378 Twenty-second ring zone First step 1.24332 Second step 1.24589 Third step 1.24849 Fourth step 1.25113 Fifth step 1.25378 Sixth step 6.28230 Twenty-third ring zone First step 1.25918 Second step 1.26192 Third step 1.26470 Fourth step 1.26750 Fifth step 1.27034 Sixth step 6.36607 Twenty-fourth ring zone First step 1.27611 Second step 1.27905 Third step 1.28203 Fourth step 1.28505 Fifth step 1.28810 Sixth step 6.45599 Twenty-fifth ring zone First step 1.29433 Second step 1.29752 Third step 1.30074 Fourth step 1.30401 Fifth step 1.30734 Sixth step 6.55356

TABLE 43F Depth [μm] Twenty-sixth ring zone First step 1.31414 Second step 1.31762 Third step 1.32116 Fourth step 1.32476 Fifth step 1.32843 Sixth step 6.66080 Twenty-seventh ring zone First step 1.33597 Second step 1.33984 Third step 1.34380 Fourth step 1.34782 Fifth step 1.35194 Sixth step 6.78077 Twenty-eighth ring zone First step 1.36045 Second step 1.36485 Third step 1.36934 Fourth step 1.37395 Fifth step 1.37867

Table 44 shows step heights of the stair-like diffraction structure provided on the second region of Example 6. In one cycle of the stair-like diffraction structure, the height of each of the first to seventh steps is set such that a phase difference of 1.25 wavelengths is provided to the light of the designed wavelength for BD, and the height of the eighth step is set such that a phase difference of 8.75 wavelengths is provided in the opposite direction.

TABLE 44 Depth [μm] First ring zone First step 1.33470 Second step 1.33995 Third step 1.34543 Fourth step 1.35111 Fifth step 1.35706 Sixth step 1.36328 Seventh step 1.36976 Eighth step 9.63594 Second ring zone First step 1.38370 Second step 1.39120 Third step 1.39909 Fourth step 1.40740 Fifth step 1.41618 Sixth step 1.42546 Seventh step 1.43530 Eighth step 10.12016

It should be noted that although not shown, the 4-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element increases is provided on the third region of Example 6. The sawtooth-like diffraction structure is provided on the outer region of Example 6.

Table 45 shows diffraction efficiencies at the twenty-eighth ring zone of the first region and at the second ring zone of the second region. The second ring zone of the second region is an outermost region which contributes to formation of a spot of light for CD in the present example.

TABLE 45 Diffractive efficiency (%) BD Inner region First ring zone 67 Twenty-eighth ring zone 45 Middle region Second ring zone 57 DVD Inner region First ring zone 71 Twenty-eighth ring zone 49 Middle region Second ring zone 30 CD Inner region First ring zone 65 Twenty-eighth ring zone 32 Middle region Second ring zone 17

The ring zone cycle of the twenty-eighth ring zone of the first region is about 14 μm, and the diffraction efficiency of the light for BD is about 45%. Meanwhile, the ring zone cycle of the first ring zone of the first region is about 144 μm, and the diffraction efficiency of the light for BD is about 67%. Thus, the diffraction efficiency of the light for BD at the twenty-eighth ring zone of the first region is much lower than the diffraction efficiency at the first ring zone. When the present invention is not applied, an amount of light in reproducing/recording on BD is insufficient with this diffraction efficiency.

In contrast, the ring zone cycle of the second ring zone of the second region is about 21 μm. The diffraction efficiency of the light for BD at the second ring zone of the second region is about 57% and is greatly improved as compared to the diffraction efficiency at the twenty-eighth ring zone of the first region. Thus, insufficiency of the light amount in reproducing/recording on BD is suppressed.

Example 7

Example 7 corresponds to the third embodiment. The first surface of an objective lens element according to Example 3 is divided into a first region including a symmetry axis, a second region surrounding the first region, and an outer region surrounding the second region. An 8-level stair-like diffraction structure whose height monotonically decreases step by step as distance from the optical axis of the objective lens element decreases is provided on the first region of the first surface. A 4-level stair-like diffraction structure whose height monotonically increases step by step as distance from the optical axis of the objective lens element increases is provided on the second region. A sawtooth-like diffraction structure is provided on the outer region. The second surface is an aspheric surface. The objective lens element according to Example 7 is a BD/DVD/CD compatible lens. With regard to designed values for BD, the wavelength is 408 nm; the focal length is 1.80 mm; and the protective layer thickness of an information storage medium is 0.0875 mm. With regard to designed values for DVD, the wavelength is 658 nm; the focal length is 2.0 mm; and the protective layer thickness of an information storage medium is 0.6 mm. With regard to designed values for CD, the wavelength is 785 nm; the focal length is 2.1 mm; and the protective layer thickness of an information storage medium is 1.2 mm.

Tables 46 and 47 show construction data of the objective lens element according to Example 7.

TABLE 46 BD DVD CD Wavelength 0.408 0.658 0.785 Effective diameter 3.09 2.41 2.06 NA 0.86 0.6 0.47 Working distance (WD) 0.53 0.44 0.3 Disc thickness (DT) 0.0875 0.6 1.2 Focal length 1.8 2.0 2.1 First surface, First region 2 −2 −3 Diffraction order First surface, Second region_Diffraction 1 −1 — order First surface, Outer region 3 — — Diffraction order Object point (OP) ∞ −100 100 Radius of curvature at Surface No. the top Thickness Material 0 OP 1 1.211178 2.256248 n1 2 −1.6991606 WD 3 ∞ DT disc 4 ∞ Wavelength 0.408 0.658 0.785 n1 1.52173 1.50389 1.50072 disc 1.61642 1.57829 1.57203

TABLE 47 First surface First region Diffractive surface Region 0 mm-1.06 mm Aspherical constant RD 1.211178 CC −0.4471445 A0 0 A2 0 A4 0.003042451 A6 −0.002139362 A8 −0.000916782 Diffractive surface P2 −95.525682 P4 10.679966 P6 −11.044402 P8 4.2227878 First surface Second region Diffractive surface Region 1.06 mm-1.22 mm Aspherical constant RD 1.2175459 CC −0.62312929 A0 0.003755648 A2 0 A4 0.0096913 A6 0.018056743 A8 −0.007521892 A10 −0.006034092 A12 0.006817604 A14 −0.001205342 A16 −0.000204353 Diffractive surface P2 −222.89625 P4 36.546342 P6 −10.136124 First surface Outer region Diffractive surface Region 1.22 mm-1.54 mm Aspherical constant RD 1.2118213 CC −0.63998677 A0 −0.0027581 A2 0 A4 0.013731193 A6 0.016620479 A8 −0.005058364 A10 −0.002588911 A12 0.000276612 A14 0.00109062 A16 −2.11E−04 A18   2.72E−05 A20 −3.38E−05 Diffractive surface P2 −274.96935 P4 117.11955 P6 −40.810453 Second surface First region Region 0 mm-0.65 mm Aspherical constant RD −1.6991606 CC −17.689289 A0 0 A2 0 A4 0.44868592 A6 −1.838644 A8 4.607409 A10 −4.4442043 A12 −2.9706261 A14 6.2221748 Region 0.65 mm-1.22 mm Aspherical constant RD −1.7038237 CC −24.181952 A0 0.00145644 A2 0 A4 0.15414236 A6 −0.12617431 A8 −0.006173137 A10 0.014786931 A12 0.029242605 A14 −0.013049098 A16 −0.012637288 A18 0.005136492 A20 0.003026593 A22 −0.001344723

Tables 48A-48D show ring zone cycles of the stair-like step structure provided on the first region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 48A Cycle [μm] Cycle [μm] First ring zone 256.86 First step 90.30 Second step 37.63 Third step 28.92 Fourth step 24.41 Fifth step 21.53 Sixth step 19.49 Seventh step 17.94 Eighth step 16.72 Second ring zone 364.57 First step 15.72 Second step 14.89 Third step 14.17 Fourth step 13.56 Fifth step 13.01 Sixth step 12.54 Seventh step 12.11 Eighth step 11.72 Third ring zone 83.23 First step 11.37 Second step 11.05 Third step 10.75 Fourth step 10.48 Fifth step 10.23 Sixth step 10.00 Seventh step 9.78 Eighth step 9.57 Fourth ring zone 70.52 First step 9.38 Second step 9.20 Third step 9.03 Fourth step 8.87 Fifth step 8.72 Sixth step 8.57 Seventh step 8.44 Eighth step 8.30

TABLE 48B Cycle [μm] Cycle [μm] Fifth ring zone 62.34 First step 8.18 Second step 8.06 Third step 7.94 Fourth step 7.83 Fifth step 7.73 Sixth step 7.63 Seventh step 7.53 Eighth step 7.44 Sixth ring zone 56.46 First step 7.34 Second step 7.26 Third step 7.17 Fourth step 7.09 Fifth step 7.01 Sixth step 6.94 Seventh step 6.86 Eighth step 6.79 Seventh ring zone 51.96 First step 6.72 Second step 6.65 Third step 6.59 Fourth step 6.52 Fifth step 6.46 Sixth step 6.40 Seventh step 6.34 Eighth step 6.28 Eighth ring zone 48.36 First step 6.23 Second step 6.17 Third step 6.12 Fourth step 6.07 Fifth step 6.02 Sixth step 5.97 Seventh step 5.92 Eighth step 5.87

TABLE 48C Cycle [μm] Cycle [μm] Ninth ring zone 45.39 First step 5.83 Second step 5.78 Third step 5.74 Fourth step 5.69 Fifth step 5.65 Sixth step 5.61 Seventh step 5.57 Eighth step 5.53 Tenth ring zone 42.90 First step 5.49 Second step 5.45 Third step 5.41 Fourth step 5.38 Fifth step 5.34 Sixth step 5.31 Seventh step 5.27 Eighth step 5.24 Eleventh ring zone 40.77 First step 5.21 Second step 5.17 Third step 5.14 Fourth step 5.11 Fifth step 5.08 Sixth step 5.05 Seventh step 5.02 Eighth step 4.99 Twelfth ring zone 38.94 First step 4.96 Second step 4.93 Third step 4.91 Fourth step 4.88 Fifth step 4.85 Sixth step 4.83 Seventh step 4.80 Eighth step 4.78

TABLE 48D Cycle [μm] Cycle [μm] Thirteenth ring zone 37.37 First step 4.75 Second step 4.73 Third step 4.70 Fourth step 4.68 Fifth step 4.66 Sixth step 4.64 Seventh step 4.61 Eighth step 4.59 Fourteenth ring zone 36.01 First step 4.57 Second step 4.55 Third step 4.53 Fourth step 4.51 Fifth step 4.49 Sixth step 4.47 Seventh step 4.45 Eighth step 4.43 Fifteenth ring zone 34.85 First step 4.42 Second step 4.40 Third step 4.38 Fourth step 4.36 Fifth step 4.35 Sixth step 4.33 Seventh step 4.31 Eighth step 4.30 Sixteenth ring zone 33.87 First step 4.28 Second step 4.27 Third step 4.25 Fourth step 4.24 Fifth step 4.23 Sixth step 4.21 Seventh step 4.20 Eighth step 4.19

On the first region of Example 7, one ring zone cycle is composed of consecutive 8-level stair-like steps whose height monotonically increases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 48A-48D indicate the width of a ring zone in a radial direction (in a direction perpendicular to the optical axis) as indicated by an arrow in FIG. 14. On the second region, a first ring zone, a second ring zone, a third ring zone, . . . , and a sixteenth ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 14. In each ring zone, the steps are referred to as a first step, a second step, a third step, . . . , and an eighth step in order from the optical axis side toward the outer periphery side.

Tables 49A and 49B show ring zone cycles of the stair-like step structure provided on the second region of the first surface, and cycles of steps arranged in each ring zone.

TABLE 49A Cycle [μm] Cycle [μm] First ring zone 16.38 First step 4.13 Second step 4.12 Third step 4.10 Fourth step 4.09 Second ring zone 16.14 First step 4.07 Second step 4.06 Third step 4.04 Fourth step 4.03 Third ring zone 15.90 First step 4.01 Second step 4.00 Third step 3.98 Fourth step 3.97 Fourth ring zone 15.67 First step 3.95 Second step 3.94 Third step 3.93 Fourth step 3.91 Fifth ring zone 15.45 First step 3.90 Second step 3.88 Third step 3.87 Fourth step 3.85 Sixth ring zone 15.22 First step 3.84 Second step 3.83 Third step 3.81 Fourth step 3.80 Seventh ring zone 15.00 First step 3.78 Second step 3.77 Third step 3.76 Fourth step 3.74 Eighth ring zone 14.78 First step 3.73 Second step 3.72 Third step 3.70 Fourth step 3.69

TABLE 49B Cycle [μm] Cycle [μm] Ninth ring zone 14.56 First step 3.67 Second step 3.66 Third step 3.65 Fourth step 3.63 Tenth ring zone 14.35 First step 3.62 Second step 3.61 Third step 3.59 Fourth step 3.58

On the second region of Example 6, one ring zone cycle is composed of consecutive 4-level stair-like steps whose height monotonically increases step by step as distance from the optical axis of the objective lens element increases. Each ring zone cycle in Tables 49A and 49B indicate the width of a ring zone in the radial direction (in the direction perpendicular to the optical axis) as indicated by an arrow in FIG. 14. On the second region, a first ring zone, a second ring zone, a third ring zone, . . . , and a tenth ring zone are provided in order from the optical axis side toward the outer periphery side of the objective lens element. Further, each step cycle indicates the width, in the radial direction (in the direction perpendicular to the optical axis), of a step provided in each ring zone, as indicated by an arrow in FIG. 14. In each ring zone, the steps are referred to as a first step, a second step, a third step, and a fourth step in order from the optical axis side toward the outer periphery side.

Tables 50A-50D shows step heights of the stair-like diffraction structure provided on the first region of Example 7. In one cycle of the stair-like diffraction structure, the height of each of the first to seventh steps is set such that a phase difference of 1.33 wavelengths is provided to light of the designed wavelength for BD, and the height of the eighth step is set such that a phase difference of 6.65 wavelengths is provided in the opposite direction.

TABLE 50A Depth [μm] First ring zone First step 0.97858 Second step 0.97964 Third step 0.98070 Fourth step 0.98178 Fifth step 0.98286 Sixth step 0.98394 Seventh step 0.98504 Eighth step 6.90296 Second ring zone First step 0.98724 Second step 0.98836 Third step 0.98948 Fourth step 0.99060 Fifth step 0.99174 Sixth step 0.99288 Seventh step 0.99403 Eighth step 6.96623 Third ring zone First step 0.99634 Second step 0.99751 Third step 0.99869 Fourth step 0.99986 Fifth step 1.00105 Sixth step 1.00225 Seventh step 1.00345 Eighth step 7.03264 Fourth ring zone First step 1.00588 Second step 1.00710 Third step 1.00834 Fourth step 1.00958 Fifth step 1.01081 Sixth step 1.01206 Seventh step 1.01333 Eighth step 7.10211

TABLE 50B Depth [μm] Fifth ring zone First step 1.01586 Second step 1.01715 Third step 1.01844 Fourth step 1.01973 Fifth step 1.02103 Sixth step 1.02234 Seventh step 1.02365 Eighth step 7.17483 Sixth ring zone First step 1.02631 Second step 1.02765 Third step 1.02899 Fourth step 1.03034 Fifth step 1.03170 Sixth step 1.03308 Seventh step 1.03445 Eighth step 7.25078 Seventh ring zone First step 1.03721 Second step 1.03861 Third step 1.04001 Fourth step 1.04143 Fifth step 1.04285 Sixth step 1.04428 Seventh step 1.04571 Eighth step 7.33005 Eighth ring zone First step 1.04860 Second step 1.05006 Third step 1.05153 Fourth step 1.05300 Fifth step 1.05449 Sixth step 1.05598 Seventh step 1.05748 Eighth step 7.41283

TABLE 50C Depth [μm] Ninth ring zone First step 1.06049 Second step 1.06201 Third step 1.06354 Fourth step 1.06508 Fifth step 1.06663 Sixth step 1.06818 Seventh step 1.06974 Eighth step 7.49919 Tenth ring zone First step 1.07289 Second step 1.07448 Third step 1.07608 Fourth step 1.07768 Fifth step 1.07929 Sixth step 1.08091 Seventh step 1.08254 Eighth step 7.58923 Eleventh ring zone First step 1.08583 Second step 1.08749 Third step 1.08915 Fourth step 1.09083 Fifth step 1.09251 Sixth step 1.09420 Seventh step 1.09590 Eighth step 7.68329 Twelfth ring zone First step 1.09934 Second step 1.10108 Third step 1.10281 Fourth step 1.10456 Fifth step 1.10633 Sixth step 1.10810 Seventh step 1.10988 Eighth step 7.78173

TABLE 50D Depth [μm] Thirteenth ring zone First step 1.11348 Second step 1.11529 Third step 1.11711 Fourth step 1.11895 Fifth step 1.12079 Sixth step 1.12265 Seventh step 1.12451 Eighth step 7.88480 Fourteenth ring zone First step 1.12829 Second step 1.13019 Third step 1.13210 Fourth step 1.13403 Fifth step 1.13596 Sixth step 1.13791 Seventh step 1.13988 Eighth step 7.99304 Fifteenth ring zone First step 1.14385 Second step 1.14585 Third step 1.14786 Fourth step 1.14989 Fifth step 1.15194 Sixth step 1.15399 Seventh step 1.15606 Eighth step 8.10705 Sixteenth ring zone First step 1.16025 Second step 1.16236 Third step 1.16449 Fourth step 1.16664 Fifth step 1.16880 Sixth step 1.17098 Seventh step 1.17316 Eighth step 8.22763

Tables 51A and 51B show step heights of the stair-like diffraction structure provided on the second region of Example 6. In one cycle of the stair-like diffraction structure, the height of each of the first to third steps is set such that a phase difference of 1.25 wavelengths is provided to the light of the designed wavelength for BD, and the height of the fourth step is set such that a phase difference of 8.75 wavelengths is provided in the opposite direction.

TABLE 51A Depth [μm] First ring zone First step 1.18405 Second step 1.18635 Third step 1.18866 Fourth step 3.57300 Second ring zone First step 1.19335 Second step 1.19571 Third step 1.19810 Fourth step 3.60154 Third ring zone First step 1.20294 Second step 1.20538 Third step 1.20783 Fourth step 3.63094 Fourth ring zone First step 1.21280 Second step 1.21531 Third step 1.21785 Fourth step 3.66120 Fifth ring zone First step 1.22298 Second step 1.22556 Third step 1.22816 Fourth step 3.69236 Sixth ring zone First step 1.23344 Second step 1.23610 Third step 1.23878 Fourth step 3.72443 Seventh ring zone First step 1.24420 Second step 1.24694 Third step 1.24969 Fourth step 3.75739 Eighth ring zone First step 1.25525 Second step 1.25806 Third step 1.26089 Fourth step 3.79118

TABLE 51B Depth [μm] Ninth ring zone First step 1.26659 Second step 1.26948 Third step 1.27236 Fourth step 3.82583 Tenth ring zone First step 1.27820 Second step 1.28115 Third step 1.28410 Fourth step 3.86123

It should be noted that although not shown, the sawtooth-like diffraction structure is provided on the outer region of Example 7.

Table 52 shows object point distances in Examples 6 and 7.

TABLE 52 unit: mm Example 6 7 L1 −200 −100 L2 100 100

The present invention can be used for an objective lens element used for performing at least one of recording, reproducing, and erasing of information on optical discs of a plurality of standards for which light of different wavelengths is used, and for an optical head device including the objective lens element.

While the invention has been described in detail, the foregoing description is in all aspects illustrative and not restrictive. It will be understood that numerous other modifications and variations can be devised without departing from the scope of the invention. 

What is claimed is:
 1. An objective lens element configured for converging each of light of a first wavelength, light of a second wavelength longer than the first wavelength, and light of a third wavelength longer than the second wavelength on an information recording surface of an optical disc, the objective lens element being configured such that: L1<0  (3), L2>0  (4), where, L1 is a first distance from an incident surface of the objective lens element to an object point of a light source of the second wavelength, and L2 is a second distance from the incident surface of the objective lens element to an object point of a light source of the third wavelength.
 2. An optical head device configured for converging a first incident light beam of a first wavelength through a base plate of a first thickness to form a spot, a second incident light beam of a second wavelength, longer than the first wavelength, through a base plate of a second thickness, larger than the first thickness, to form a spot, and a third incident light beam of a third wavelength, longer than the second wavelength, through a base plate of a third thickness, larger than the second thickness, to form a spot, the optical head device comprising: a first light source configured for emitting a light beam of the first wavelength; a second light source configured for emitting a light beam of the second wavelength; a third light source configured for emitting a light beam of the third wavelength; an objective lens element according to claim 1; and a detection element configured for detecting light reflected by an information recording surface of an optical disc. 